JP2021011491A - Antigen-binding molecule binding to a plurality of antigen molecules repeatedly - Google Patents
Antigen-binding molecule binding to a plurality of antigen molecules repeatedly Download PDFInfo
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- JP2021011491A JP2021011491A JP2020169016A JP2020169016A JP2021011491A JP 2021011491 A JP2021011491 A JP 2021011491A JP 2020169016 A JP2020169016 A JP 2020169016A JP 2020169016 A JP2020169016 A JP 2020169016A JP 2021011491 A JP2021011491 A JP 2021011491A
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- histidine
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Abstract
Description
本発明は、抗原結合分子の薬物動態を向上する方法、抗原結合分子の抗原への結合回数を増やす方法、薬物動態が向上した抗原結合分子、抗原結合分子の抗原への結合回数が向上した抗原結合分子、および、それらの製造法等に関する。 The present invention relates to a method for improving the pharmacokinetics of an antigen-binding molecule, a method for increasing the number of times an antigen-binding molecule binds to an antigen, an antigen-binding molecule with improved pharmacokinetics, and an antigen having an improved number of times an antigen-binding molecule binds to an antigen. It relates to a binding molecule and a method for producing them.
抗体は血漿中での安定性が高く、副作用も少ないことから医薬品として注目されている。中でもIgG型の抗体医薬は多数上市されており、現在も数多くの抗体医薬が開発されている(非特許文献1、非特許文献2)。一方、第2世代の抗体医薬に適用可能な技術として様々な技術が開発されており、エフェクター機能、抗原結合能、薬物動態、安定性を向上させる、あるいは、免疫原性リスクを低減させる技術等が報告されている(非特許文献3)。抗体医薬は一般に投与量が非常に高いため、皮下投与製剤の作製が困難であること、製造コストが高いこと等が課題として考えられる。抗体医薬の投与量を低減させる方法として、抗体の薬物動態を向上する方法と抗体と抗原の親和性(アフィニティー)を向上する方法が考えられる。
Antibodies are attracting attention as pharmaceuticals because they are highly stable in plasma and have few side effects. Among them, many IgG-type antibody drugs have been put on the market, and many antibody drugs are still being developed (Non-Patent
抗体の薬物動態を向上させる方法として、定常領域の人工的なアミノ酸置換が報告されている(非特許文献4、5)。抗原結合能、抗原中和能を増強させる技術として、アフィニティーマチュレーション技術(非特許文献6)が報告されており、可変領域のCDR領域などのアミノ酸に変異を導入することで抗原への結合活性を増強することが可能である。抗原結合能の増強によりin vitroの生物活性を向上させる、あるいは投与量を低減することが可能であり、さらにin vivoでの薬効を向上させることも可能である(非特許文献7)。
As a method for improving the pharmacokinetics of an antibody, artificial amino acid substitution in a constant region has been reported (Non-Patent
一方、抗体1分子あたりが中和できる抗原量はアフィニティーに依存し、アフィニティーを強くすることで少ない抗体量で抗原を中和することが可能であり、様々な方法で抗体のアフィニティーを強くすることが可能である。さらに抗原に共有結合的に結合し、アフィニティーを無限大にすることができれば1分子の抗体で1分子の抗原(2価の場合は2抗原)を中和することが可能である。しかし、これまでの方法では1分子の抗体で1分子の抗原(2価の場合は2抗原)の化学量論的な中和反応が限界であり、抗原量以下の抗体量で抗原を完全に中和することは不可能であった。つまり、アフィニティーを強くする効果には限界が存在していた(非特許文献9)。中和抗体の場合、その中和効果を一定期間持続させるためには、その期間に生体内で産生される抗原量以上の抗体量が投与される必要があり、上述の抗体の薬物動態向上、あるいは、アフィニティーマチュレーション技術だけでは、必要抗体投与量の低減には限界が存在していた。 On the other hand, the amount of antigen that can be neutralized per antibody molecule depends on the affinity, and it is possible to neutralize the antigen with a small amount of antibody by strengthening the affinity, and strengthening the affinity of the antibody by various methods. Is possible. Further, if it can covalently bind to an antigen and the affinity can be made infinite, it is possible to neutralize one molecule of the antigen (two antigens in the case of divalent) with one molecule of the antibody. However, in the conventional methods, the pharmacological neutralization reaction of one molecule of antigen (two antigens in the case of divalent) is the limit with one molecule of antibody, and the antigen is completely neutralized with an antibody amount less than the antigen amount. It was impossible to neutralize. That is, there is a limit to the effect of strengthening affinity (Non-Patent Document 9). In the case of a neutralizing antibody, in order to maintain the neutralizing effect for a certain period of time, it is necessary to administer an antibody amount equal to or greater than the amount of the antigen produced in the living body during that period, and the pharmacokinetics of the above-mentioned antibody is improved. Alternatively, there was a limit to the reduction of the required antibody dose only by the affinity maturation technique.
そのため、抗原量以下の抗体量で抗原の中和効果を目的期間持続するためには、一つの抗体で複数の抗原を中和する必要がある。1つの抗体で複数の抗原を中和する方法として、抗体に触媒機能を付与した触媒抗体による抗原の不活化が挙げられる。タンパク質抗原の場合、抗原のペプチド結合を加水分解することで不活化することが可能であり、この加水分解反応を抗体が触媒することで、繰り返し抗原を中和(不活化)することが可能であると考えられている(非特許文献8)。これまでに多くの触媒抗体および触媒抗体作製技術に関する報告がされているが、医薬品として十分な触媒活性を有する触媒抗体の報告はない。すなわち、ある抗原に対する抗体のin vivo試験において、通常の触媒機能を有さない中和抗体と比較して、低用量で同等以上の効果を発揮する、あるいは、同じ投与量でより持続的に効果を発揮することができる触媒抗体の報告はこれまでにない。 Therefore, in order to maintain the effect of neutralizing an antigen for a target period with an antibody amount equal to or less than the amount of the antigen, it is necessary to neutralize a plurality of antigens with one antibody. As a method of neutralizing a plurality of antigens with one antibody, inactivation of antigens by a catalytic antibody in which a catalytic function is imparted to the antibody can be mentioned. In the case of a protein antigen, it can be inactivated by hydrolyzing the peptide bond of the antigen, and the antibody can catalyze this hydrolysis reaction to repeatedly neutralize (inactivate) the antigen. It is believed that there is (Non-Patent Document 8). Although many catalyst antibodies and catalyst antibody production techniques have been reported so far, there are no reports of catalyst antibodies having sufficient catalytic activity as pharmaceuticals. That is, in an in vivo test of an antibody against a certain antigen, the effect is equal to or higher than that of a neutralizing antibody having no normal catalytic function, or the effect is more sustained at the same dose. There has been no report of a catalytic antibody capable of exerting this.
このように、1分子の抗体で複数の抗原を中和し、通常の中和抗体より優れたin vivo効果を発揮することができる抗体に関する報告はなく、投与量の低減および持続性の延長のためには1抗体で複数の抗原を中和し、in vivoで通常の中和抗体よりも効果を発揮する新規な抗体作製技術が望まれていた。 As described above, there is no report on an antibody capable of neutralizing a plurality of antigens with one molecule and exerting a superior in vivo effect than a normal neutralizing antibody, and the dose is reduced and the duration is extended. For this purpose, a novel antibody production technique has been desired in which a single antibody neutralizes a plurality of antigens and exerts more effect than a normal neutralizing antibody in vivo.
なお、本発明の先行技術文献を以下に示す。 The prior art documents of the present invention are shown below.
本発明はこのような状況に鑑みて為されたものであり、その目的は抗原結合分子が抗原に複数回結合する方法、抗原結合分子の薬物動態を向上させる方法、複数回抗原に結合できる抗原結合分子、薬物動態が改善された抗原結合分子、当該抗原結合分子を含む医薬組成物、およびそれらの製造方法を提供することにある。 The present invention has been made in view of such a situation, and an object of the present invention is a method in which an antigen-binding molecule binds to an antigen multiple times, a method for improving the pharmacokinetics of the antigen-binding molecule, and an antigen capable of binding to an antigen multiple times. It is an object of the present invention to provide a binding molecule, an antigen-binding molecule having improved pharmacokinetics, a pharmaceutical composition containing the antigen-binding molecule, and a method for producing the same.
本発明者らは、抗原結合分子などの抗原結合能を有するポリペプチドの抗原に複数回結合する方法、血漿中半減期(血中半減期)を改善(薬物動態を向上)する方法について、鋭意研究を行った。その結果、本発明者らは、血漿中(血中)でのpHにおける抗原結合活性と比較して早期エンドソーム内でのpHにおける抗原結合活性が弱い抗原結合分子は抗原に複数回結合し、血漿中半減期が長いことを見出した。 The present inventors are keen on a method of binding to an antigen of a polypeptide having an antigen-binding ability such as an antigen-binding molecule multiple times, and a method of improving plasma half-life (blood half-life) (improving pharmacokinetics). I did a study. As a result, the present inventors have weakened the antigen-binding activity at pH in early endosomes as compared with the antigen-binding activity at pH in plasma (blood), and the antigen-binding molecule binds to the antigen multiple times and plasma. We found that the medium half-life was long.
本発明は、抗原結合分子が抗原に複数回結合する方法、抗原結合分子の薬物動態を向上する方法、複数回抗原に結合できる抗原結合分子、薬物動態が向上した抗原結合分子、薬物動態が向上した抗原結合分子の製造方法などに関し、より具体的には、
〔1〕抗原に対するpH5.8でのKDとpH7.4でのKDの比であるKD(pH5.8)/KD(pH7.4)の値が2以上である抗原結合分子、
〔2〕KD(pH5.8)/KD(pH7.4)の値が10以上である〔1〕に記載の抗原結合分子、
〔3〕KD(pH5.8)/KD(pH7.4)の値が40以上である〔1〕に記載の抗原結合分子、
〔4〕少なくとも1つのアミノ酸がヒスチジンで置換され又は少なくとも1つのヒスチジンが挿入されていることを特徴とする〔1〕〜〔3〕いずれかに記載の抗原結合分子、
〔5〕アンタゴニスト活性を有することを特徴とする〔1〕〜〔4〕いずれかに記載の抗原結合分子、
〔6〕膜抗原又は可溶型抗原に結合することを特徴とする〔1〕〜〔5〕いずれかに記載の抗原結合分子、
〔7〕抗原結合分子が抗体であることを特徴とする〔1〕〜〔6〕いずれかに記載の抗原結合分子、
〔8〕〔1〕〜〔7〕いずれかに記載の抗原結合分子を含む医薬組成物、
〔9〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより抗原結合分子の薬物動態を向上させる方法、
〔10〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより、抗原結合分子の抗原への結合回数を増やす方法、
〔11〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより、抗原結合分子が結合可能な抗原の数を増やす方法、
〔12〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法、
〔13〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法、
〔14〕抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くすることにより、抗原結合分子の血漿中抗原消失能を増加させる方法、
〔15〕抗原に対するpH5.8でのKDとpH7.4でのKDの比であるKD(pH5.8)/KD(pH7.4)の値を2以上とすることを特徴とする〔9〕〜〔14〕いずれかに記載の方法、
〔16〕KD(pH5.8)/KD(pH7.4)の値を10以上とすることを特徴とする〔9〕〜〔14〕いずれかに記載の方法、
〔17〕KD(pH5.8)/KD(pH7.4)の値を40以上とすることを特徴とする〔9〕〜〔14〕いずれかに記載の方法、
〔18〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより薬物動態を向上させる方法、
〔19〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより、抗原結合分子の抗原への結合回数を増やす方法、
〔20〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより、抗原結合分子が結合可能な抗原の数を増やす方法、
〔21〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法、
〔22〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法、
〔23〕抗原結合分子の少なくとも1つのアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入することにより、抗原結合分子の血漿中抗原消失能を増加させる方法、
〔24〕ヒスチジンへの置換又はヒスチジンの挿入により、pH5.8での抗原結合活性とpH7.4での抗原結合活性の比であるKD(pH5.8)/KD(pH7.4)の値がヒスチジン置換又は挿入前と比較して大きくなることを特徴とする〔18〕〜〔23〕いずれかに記載の方法、
〔25〕抗原結合分子がアンタゴニスト活性を有することを特徴とする〔9〕〜〔24〕いずれかに記載の方法、
〔26〕抗原結合分子が膜抗原又は可溶型抗原に結合することを特徴とする〔9〕〜〔25〕いずれかに記載の方法、
〔27〕抗原結合分子が抗体であることを特徴とする〔9〕〜〔26〕いずれかに記載の方法、
〔28〕以下の工程を含む抗原結合分子のスクリーニング方法、
(a)pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b)pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c)pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程、
〔29〕pH6.7〜pH10.0における抗原結合活性がpH4.0〜pH6.5での抗原結合活性の2倍以上である抗体を選択することを特徴とする〔28〕に記載のスクリーニング方法、
〔30〕以下の工程を含む抗原結合分子のスクリーニング方法、
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
〔31〕以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子のスクリーニング方法、
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程、
〔32〕以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子のスクリーニング方法、
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程、
〔33〕第一のpHがpH6.7.〜pH10.0、第二のpHが4.0〜pH6.5であることを特徴とする〔31〕または〔32〕に記載のスクリーニング方法、
〔34〕抗原結合分子が、抗原結合分子中の少なくとも1つ以上のアミノ酸がヒスチジンで置換された又は少なくとも1つのヒスチジンが挿入された抗原結合分子である〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔35〕血漿中滞留性が優れた抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔36〕抗原に2回以上結合することができる抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔37〕結合可能な抗原の数が抗原結合部位より多い抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔38〕細胞外で結合した抗原を細胞内で解離する抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔39〕抗原と結合した状態で細胞内に取り込まれ、抗原と結合していない状態で細胞外に放出される抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔40〕血漿中抗原消失能が増加した抗原結合分子を得ることを目的とする〔28〕〜〔33〕いずれかに記載のスクリーニング方法、
〔41〕抗原結合分子が医薬組成物として用いられる抗原結合分子である〔28〕〜〔40〕いずれかに記載のスクリーニング方法、
〔42〕抗原結合分子が抗体であることを特徴とする〔28〕〜〔41〕いずれかに記載のスクリーニング方法、
〔43〕以下の工程を含む抗原結合分子の製造方法、
(a) pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b) pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c) pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程、
(d) (c)で選択された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程、
〔44〕以下の工程を含む抗原結合分子の製造方法、
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程、
〔45〕以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子の製造方法、
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程、
〔46〕以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子の製造方法、
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程、
(e) (d)で取得された抗原結合分子をコードする遺伝子を得る工程、
(f) (e)で得られた遺伝子を用いて抗原結合分子を製造する工程、
〔47〕第一のpHがpH6.7.〜pH10.0、第二のpHが4.0〜pH6.5であることを特徴とする〔45〕または〔46〕に記載の製造方法、
〔48〕抗原結合分子中の少なくとも1つ以上のアミノ酸をヒスチジンで置換する又は少なくとも1つのヒスチジンを挿入する工程をさらに含む〔43〕〜〔47〕いずれかに記載の製造方法、
〔49〕抗原結合分子が抗体であることを特徴とする〔43〕〜〔48〕いずれかに記載の製造方法、
〔50〕〔43〕〜〔49〕いずれかに記載の製造方法により製造された抗原結合分子を含む医薬組成物、
を提供するものである。
The present invention relates to a method in which an antigen-binding molecule binds to an antigen multiple times, a method for improving the pharmacokinetics of the antigen-binding molecule, an antigen-binding molecule capable of binding to an antigen multiple times, an antigen-binding molecule with improved pharmacokinetics, and improved pharmacokinetics. More specifically, regarding the method for producing the antigen-binding molecule,
[1] An antigen-binding molecule having a KD (pH 5.8) / KD (pH 7.4) value of 2 or more, which is the ratio of KD at pH 5.8 to KD at pH 7.4 with respect to the antigen.
[2] The antigen-binding molecule according to [1], wherein the value of KD (pH 5.8) / KD (pH 7.4) is 10 or more.
[3] The antigen-binding molecule according to [1], wherein the value of KD (pH 5.8) / KD (pH 7.4) is 40 or more.
[4] The antigen-binding molecule according to any one of [1] to [3], wherein at least one amino acid is replaced with histidine or at least one histidine is inserted.
[5] The antigen-binding molecule according to any one of [1] to [4], which has antagonistic activity.
[6] The antigen-binding molecule according to any one of [1] to [5], which binds to a membrane antigen or a soluble antigen.
[7] The antigen-binding molecule according to any one of [1] to [6], wherein the antigen-binding molecule is an antibody.
[8] A pharmaceutical composition containing the antigen-binding molecule according to any one of [1] to [7].
[9] A method for improving the pharmacokinetics of an antigen-binding molecule by weakening the antigen-binding activity of the antigen-binding molecule at pH 5.8 to weaker than the antigen-binding activity at pH 7.4.
[10] A method for increasing the number of times an antigen-binding molecule binds to an antigen by making the antigen-binding activity of the antigen-binding molecule weaker than the antigen-binding activity at pH 7.4.
[11] A method for increasing the number of antigens to which an antigen-binding molecule can bind by making the antigen-binding activity of the antigen-binding molecule at pH 5.8 weaker than that at pH 7.4.
[12] A method for dissociating an antigen bound to an antigen-binding molecule extracellularly from the antigen-binding molecule intracellularly by making the antigen-binding activity of the antigen-binding molecule weaker than the antigen-binding activity at pH 7.4.
[13] By making the antigen-binding activity of the antigen-binding molecule at pH 5.8 weaker than the antigen-binding activity at pH 7.4, the antigen-binding molecule taken up into the cell in a state of being bound to the antigen is bound to the antigen. How to release it extracellularly without it,
[14] A method for increasing the plasma antigen elimination ability of an antigen-binding molecule by making the antigen-binding activity of the antigen-binding molecule weaker than the antigen-binding activity at pH 7.4.
[15] The value of KD (pH 5.8) / KD (pH 7.4), which is the ratio of KD at pH 5.8 to KD at pH 7.4 with respect to the antigen, is set to 2 or more [9]. ~ [14] The method according to any one of
[16] The method according to any one of [9] to [14], wherein the value of KD (pH 5.8) / KD (pH 7.4) is 10 or more.
[17] The method according to any one of [9] to [14], wherein the value of KD (pH 5.8) / KD (pH 7.4) is 40 or more.
[18] A method for improving pharmacokinetics by substituting at least one amino acid of an antigen-binding molecule with histidine or inserting at least one histidine.
[19] A method for increasing the number of times an antigen-binding molecule binds to an antigen by substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine.
[20] A method for increasing the number of antigens to which an antigen-binding molecule can bind by substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine.
[21] A method for dissociating an antigen bound to an antigen-binding molecule extracellularly from the antigen-binding molecule intracellularly by substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine.
[22] By substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine, the antigen-binding molecule incorporated into the cell in a state of being bound to the antigen is not bound to the antigen. How to release it extracellularly in the state,
[23] A method for increasing the ability of an antigen-binding molecule to eliminate antigen in plasma by substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine.
[24] By substitution with histidine or insertion of histidine, the value of KD (pH 5.8) / KD (pH 7.4), which is the ratio of the antigen-binding activity at pH 5.8 to the antigen-binding activity at pH 7.4, is increased. The method according to any one of [18] to [23], which is characterized by being larger than that before histidine substitution or insertion.
[25] The method according to any one of [9] to [24], wherein the antigen-binding molecule has an antagonistic activity.
[26] The method according to any one of [9] to [25], wherein the antigen-binding molecule binds to a membrane antigen or a soluble antigen.
[27] The method according to any one of [9] to [26], wherein the antigen-binding molecule is an antibody.
[28] A method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5,
[29] The screening method according to [28], wherein an antibody having an antigen-binding activity at pH 6.7 to pH 10.0 that is at least twice the antigen-binding activity at pH 4.0 to pH 6.5 is selected. ,
[30] A method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
[31] A method for screening an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, which comprises the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) Step of obtaining the eluted antigen-binding molecule,
[32] A method for screening an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, which comprises the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) Step of obtaining the eluted antigen-binding molecule,
[33] The screening method according to [31] or [32], wherein the first pH is pH 6.7. To pH 10.0 and the second pH is 4.0 to pH 6.5.
[34] The antigen-binding molecule is any of [28] to [33], wherein the antigen-binding molecule is an antigen-binding molecule in which at least one or more amino acids in the antigen-binding molecule are replaced with histidine or at least one histidine is inserted. Screening method,
[35] The screening method according to any one of [28] to [33], which aims to obtain an antigen-binding molecule having excellent plasma retention.
[36] The screening method according to any one of [28] to [33], which aims to obtain an antigen-binding molecule capable of binding to an antigen more than once.
[37] The screening method according to any one of [28] to [33], wherein the number of antigens that can be bound is larger than that of the antigen binding site.
[38] The screening method according to any one of [28] to [33], which aims to obtain an antigen-binding molecule that dissociates an antigen bound extracellularly into the cell.
[39] The invention according to any one of [28] to [33], wherein an antigen-binding molecule is taken into the cell in a state of being bound to an antigen and released extracellularly in a state of not being bound to an antigen. Screening method,
[40] The screening method according to any one of [28] to [33], which aims to obtain an antigen-binding molecule having an increased ability to eliminate antigen in plasma.
[41] The screening method according to any one of [28] to [40], wherein the antigen-binding molecule is an antigen-binding molecule used as a pharmaceutical composition.
[42] The screening method according to any one of [28] to [41], wherein the antigen-binding molecule is an antibody.
[43] A method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule selected in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d),
[44] A method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d),
[45] A method for producing an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, which comprises the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) Step of obtaining the eluted antigen-binding molecule,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d),
[46] A method for producing an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, which comprises the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) Step of obtaining the eluted antigen-binding molecule,
(e) The step of obtaining the gene encoding the antigen-binding molecule obtained in (d),
(f) A step of producing an antigen-binding molecule using the gene obtained in (e),
[47] The production method according to [45] or [46], wherein the first pH is pH 6.7. To pH 10.0 and the second pH is 4.0 to pH 6.5.
[48] The production method according to any one of [43] to [47], further comprising the step of substituting at least one or more amino acids in the antigen-binding molecule with histidine or inserting at least one histidine.
[49] The production method according to any one of [43] to [48], wherein the antigen-binding molecule is an antibody.
[50] A pharmaceutical composition containing an antigen-binding molecule produced by the production method according to any one of [43] to [49].
Is to provide.
本発明によって、1分子の抗原結合分子を複数の抗原に繰り返し結合させる方法が提供された。1分子の抗原結合分子が複数の抗原に結合することで抗原結合分子の薬物動態を向上させ、in vivoにおいて通常の抗原結合分子よりも優れた効果を発揮させることができる。 The present invention provides a method of repeatedly binding one antigen-binding molecule to a plurality of antigens. By binding one antigen-binding molecule to a plurality of antigens, the pharmacokinetics of the antigen-binding molecule can be improved, and an effect superior to that of a normal antigen-binding molecule can be exhibited in vivo.
〔発明を実施するための形態〕
本発明は、抗原結合分子の抗原への結合回数を増やす方法を提供する。より具体的には抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子の抗原への結合回数を増やす方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする抗原結合分子の抗原への結合回数を増やす方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする抗原結合分子の抗原への結合回数を増やす方法を提供する。
[Mode for carrying out the invention]
The present invention provides a method for increasing the number of times an antigen-binding molecule binds to an antigen. More specifically, the present invention provides a method for increasing the number of times an antigen-binding molecule binds to an antigen by making the antigen-binding ability of the antigen-binding molecule at an acidic pH weaker than that at a neutral pH. Furthermore, the present invention provides a method for increasing the number of times an antigen-binding molecule binds to an antigen, which comprises substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine. Furthermore, the present invention provides a method for increasing the number of times an antigen-binding molecule binds to an antigen, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule.
又、本発明は、抗原結合分子が結合可能な抗原の数を増やす方法を提供する。より具体的には抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子が結合可能な抗原の数を増やす方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする、抗原結合分子が結合可能な抗原の数を増やす方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする抗原結合分子が結合可能な抗原の数を増やす方法を提供する。 The present invention also provides a method for increasing the number of antigens to which an antigen-binding molecule can bind. More specifically, the present invention provides a method for increasing the number of antigens to which an antigen-binding molecule can bind by making the antigen-binding ability of the antigen-binding molecule at an acidic pH weaker than that at a neutral pH. Furthermore, the present invention provides a method for increasing the number of antigens to which an antigen-binding molecule can bind, which comprises substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine. Furthermore, the present invention provides a method for increasing the number of antigens to which an antigen-binding molecule can bind, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule. ..
又、本発明は、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法を提供する。より具体的には抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法を提供する。 The present invention also provides a method for dissociating an antigen bound to an antigen-binding molecule extracellularly from the antigen-binding molecule intracellularly. More specifically, by making the antigen-binding ability of the antigen-binding molecule at acidic pH weaker than the antigen-binding ability at neutral pH, the antigen bound to the antigen-binding molecule outside the cell is dissociated from the antigen-binding molecule inside the cell. Provide a method. Furthermore, the present invention is characterized in that at least one amino acid of the antigen-binding molecule is replaced with histidine or at least one histidine is inserted, and an antigen bound to the antigen-binding molecule extracellularly is transferred from the antigen-binding molecule intracellularly. A method for dissociating is provided. Furthermore, the present invention comprises intracellular antigen binding to an antigen bound to an extracellular antigen-binding molecule, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule. A method for dissociating from a molecule is provided.
又、本発明は、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法を提供する。より具体的には抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法を提供する。 The present invention also provides a method for releasing an antigen-binding molecule taken into a cell in a state of being bound to an antigen to the outside of the cell in a state of not binding to an antigen. More specifically, by making the antigen-binding ability of the antigen-binding molecule at acidic pH weaker than the antigen-binding ability at neutral pH, the antigen-binding molecule incorporated into the cell in a state of being bound to the antigen is bound to the antigen. Provided is a method of releasing the antigen to the outside of the cell in the untreated state. Further, the present invention comprises substituting at least one amino acid of an antigen-binding molecule with histidine or inserting at least one histidine, wherein the antigen-binding molecule incorporated into a cell in a state of being bound to an antigen is used as an antigen. Provided is a method for releasing to the outside of a cell in a state where it is not bound to. Furthermore, the present invention comprises an antigen-binding molecule incorporated into a cell in a state of being bound to an antigen, which is characterized by substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule. , Provide a method for extracellular release without binding to an antigen.
又、本発明は、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。より具体的には抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。 The present invention also provides a method for increasing the plasma antigen elimination ability of an antigen-binding molecule. More specifically, the present invention provides a method for increasing the plasma antigen-eliminating ability of an antigen-binding molecule by making the antigen-binding ability of the antigen-binding molecule at an acidic pH weaker than that at a neutral pH. Furthermore, the present invention provides a method for increasing the ability of an antigen-binding molecule to eliminate antigen in plasma, which comprises substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine. Furthermore, the present invention provides a method for increasing the plasma antigen-eliminating ability of an antigen-binding molecule, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule. ..
さらに、本発明は、抗原結合分子の薬物動態を向上する方法を提供する。より具体的には、抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子の薬物動態を向上する(血漿中滞留性を長くする)方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする薬物動態を向上する方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする薬物動態を向上する方法を提供する。 Furthermore, the present invention provides a method of improving the pharmacokinetics of an antigen-binding molecule. More specifically, a method for improving the pharmacokinetics of an antigen-binding molecule (prolonging its retention in plasma) by making the antigen-binding ability of the antigen-binding molecule weaker than the antigen-binding ability at neutral pH. I will provide a. Furthermore, the present invention provides a method for improving pharmacokinetics, which comprises substituting at least one amino acid of an antigen-binding molecule with histidine or inserting at least one histidine. Furthermore, the present invention provides a method for improving pharmacokinetics, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in an antigen-binding molecule.
さらに、本発明は、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。より具体的には、抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入することを特徴とする抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。さらに本発明は、抗原結合分子に含まれる抗体定常領域中のアミノ酸を置換、欠失、付加及び/又は挿入することを特徴とする抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。 Furthermore, the present invention provides a method for increasing the plasma antigen-eliminating ability of an antigen-binding molecule. More specifically, the present invention provides a method for increasing the plasma antigen-eliminating ability of an antigen-binding molecule by weakening the antigen-binding ability of the antigen-binding molecule at acidic pH to be weaker than the antigen-binding ability at neutral pH. Furthermore, the present invention provides a method for increasing the ability of an antigen-binding molecule to eliminate antigen in plasma, which comprises substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine. Furthermore, the present invention provides a method for increasing the plasma antigen-eliminating ability of an antigen-binding molecule, which comprises substituting, deleting, adding and / or inserting an amino acid in an antibody constant region contained in the antigen-binding molecule. ..
本発明において、「薬物動態の向上」、「薬物動態の改善」または「優れた薬物動態」は、「血漿中(血中)滞留性の向上」、「血漿中(血中)滞留性の改善」、「優れた血漿中(血中)滞留性」と言い換えることが可能であり、これらの語句は同じ意味で使用される。 In the present invention, "improvement of pharmacokinetics", "improvement of pharmacokinetics" or "excellent pharmacokinetics" means "improvement of plasma (blood) retention" and "improvement of plasma (blood) retention". , "Excellent plasma (blood) retention" can be rephrased, and these terms are used interchangeably.
本発明において、酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くするとは、抗原結合分子のpH4.0〜pH6.5での抗原結合活性をpH6.7〜pH10.0での抗原結合活性より弱くすることを意味する。好ましくは、抗原結合分子のpH5.5〜pH6.5での抗原結合活性をpH7.0〜pH8.0での抗原結合活性より弱くすることを意味し、特に好ましくは、抗原結合分子のpH5.8での抗原結合活性をpH7.4での抗原結合活性より弱くすることを意味する。従って、本発明において酸性pHとは通常、pH4.0〜pH6.5であり、好ましくはpH5.5〜pH6.5であり、特に好ましくはpH5.8である。又、本発明において中性pHとは通常、pH6.7〜pH10.0であり、好ましくは、pH7.0〜pH8.0であり、特に好ましくはpH7.4である。 In the present invention, the antigen-binding ability at acidic pH is weaker than the antigen-binding ability at neutral pH, and the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5 is adjusted to pH 6.7 to pH 10.0. It means that it is weaker than the antigen-binding activity. Preferably, it means that the antigen-binding activity of the antigen-binding molecule at pH 5.5 to pH 6.5 is weaker than that of the antigen-binding activity at pH 7.0 to pH 8.0, and particularly preferably, the pH of the antigen-binding molecule is 5. It means that the antigen-binding activity at 8 is weaker than the antigen-binding activity at pH 7.4. Therefore, in the present invention, the acidic pH is usually pH 4.0 to pH 6.5, preferably pH 5.5 to pH 6.5, and particularly preferably pH 5.8. Further, in the present invention, the neutral pH is usually pH 6.7 to pH 10.0, preferably pH 7.0 to pH 8.0, and particularly preferably pH 7.4.
本発明において、「抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能より弱くする」という表現は、抗原結合分子の中性での抗原結合能を酸性でのpHにおける抗原結合能よりも高くすると表現することもできる。つまり、本発明においては、抗原結合分子の酸性pHにおける抗原結合能と中性pHにおける抗原結合能の差を大きくすればよい(例えば、後述のようにKD(pH5.8)/KD(pH7.4)の値を大きくすればよい)。抗原結合分子の酸性pHにおける抗原結合能と中性pHにおける抗原結合能の差を大きくするためには、例えば、酸性pHにおける抗原結合能を低くしてもよいし、中性pHにおける抗原結合能を高くしてもよいし、又は、その両方でもよい。
In the present invention, the expression "making the antigen-binding ability of an antigen-binding molecule weaker than the antigen-binding ability at neutral pH" means that the neutral antigen-binding ability of an antigen-binding molecule is changed to antigen-binding at acidic pH. It can also be expressed as higher than Noh. That is, in the present invention, the difference between the antigen-binding ability of the antigen-binding molecule at acidic pH and the antigen-binding ability at neutral pH may be increased (for example, KD (pH 5.8) / KD (
抗原の結合活性を測定する際のpH以外の条件は当業者が適宜選択することが可能であり、特に限定されないが、例えば、実施例に記載のようにMESバッファー、37℃の条件において測定することが可能である。又、抗原結合分子の抗原結合活性の測定は当業者に公知の方法により行うことが可能であり、例えば、実施例に記載のようにBiacore(GE Healthcare)などを用いて測定することが可能である。抗原が可溶型抗原である場合は、抗原結合分子を固定化したチップへの抗原をアナライトとして流すことで可溶型抗原への結合能を評価することが可能であり、抗原が膜型抗原である場合は、抗原を固定化したチップへ抗原結合分子をアナライトとして流すことで膜型抗原への結合能を評価することが可能である。 Conditions other than pH when measuring the binding activity of the antigen can be appropriately selected by those skilled in the art and are not particularly limited, but for example, the measurement is performed under the conditions of MES buffer and 37 ° C. as described in Examples. It is possible. Further, the antigen-binding activity of the antigen-binding molecule can be measured by a method known to those skilled in the art, and for example, it can be measured using Biacore (GE Healthcare) or the like as described in Examples. is there. When the antigen is a soluble antigen, it is possible to evaluate the binding ability to the soluble antigen by flowing the antigen to the chip on which the antigen-binding molecule is immobilized as an analyzer, and the antigen is a membrane type. In the case of an antigen, it is possible to evaluate the ability to bind to a membrane-type antigen by flowing an antigen-binding molecule as an analyzer on a chip on which the antigen is immobilized.
本発明において、酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性よりも弱い限り、酸性pHにおける抗原結合活性と中性pHにおける抗原結合活性の差は特に限定されないが、好ましくは抗原に対するpH5.8でのKDとpH7.4でのKD(Dissociation constant:解離定数)の比であるKD(pH5.8)/KD(pH7.4)の値が2以上であり、さらに好ましくはKD(pH5.8)/KD(pH7.4)の値が10以上であり、さらに好ましくはKD(pH5.8)/KD(pH7.4)の値が40以上である。KD(pH5.8)/KD(pH7.4)の値の上限は特に限定されず、当業者の技術において作製可能な限り、400、1000、10000等、いかなる値でもよい。抗原結合活性の値として抗原が可溶型抗原の場合はKD(解離定数)を用いることが可能であるが、抗原が膜型抗原の場合は見かけのKD(Apparent dissociation constant:見かけの解離定数)を用いることが可能である。KD(解離定数)、および、見かけのKD(見かけの解離定数)は、当業者公知の方法で測定することが可能であり、例えばBiacore(GE healthcare)、スキャッチャードプロット、FACS等を用いることが可能である。
In the present invention, as long as the antigen-binding activity at acidic pH is weaker than the antigen-binding activity at neutral pH, the difference between the antigen-binding activity at acidic pH and the antigen-binding activity at neutral pH is not particularly limited, but
又、本発明においては、酸性pHにおける抗原結合活性と中性pHにおける抗原結合活性の差を示す他の指標として、例えば、解離速度定数であるkd(Dissociation rate constant:解離速度定数)を用いることも可能である。結合活性の差を示す指標としてKD(解離定数)の代わりにkd(解離速度定数)を用いる場合、抗原に対するpH5.8でのkd(解離速度定数)とpH7.4でのkd(解離速度定数)の比であるkd(pH5.8)/kd(pH7.4)の値は、好ましくは2以上であり、さらに好ましくは5以上であり、さらに好ましくは10以上であり、より好ましくは30以上である。kd(pH5.8)/kd(pH7.4)の値の上限は特に限定されず、当業者の技術常識において作製可能な限り、50、100、200等、如何なる値でもよい。 Further, in the present invention, for example, k d (Dissociation rate constant), which is a dissociation rate constant, is used as another index showing the difference between the antigen-binding activity at acidic pH and the antigen-binding activity at neutral pH. It is also possible. When using the KD as an indicator of differences in binding activity k d (dissociation rate constant) instead of (dissociation constant), k d with k d and (dissociation rate constant) pH 7.4 at pH5.8 to antigen ( The value of k d (pH 5.8) / k d (pH 7.4), which is the ratio of the dissociation rate constant), is preferably 2 or more, more preferably 5 or more, still more preferably 10 or more. More preferably, it is 30 or more. The upper limit of the value of k d (pH5.8) / k d (pH7.4) is not particularly limited, as far as possible made in the skill of the art knowledge, like 50, 100, 200, may be any value.
抗原結合活性の値として抗原が可溶型抗原の場合はkd(解離速度定数)を用いることが可能であるが、抗原が膜型抗原の場合は見かけのkd(Apparent dissociation rate constant:見かけの解離速度定数)を用いることが可能である。kd(解離速度定数)、および、見かけのkd(見かけの解離速度定数)は、当業者公知の方法で測定することが可能であり、例えばBiacore(GE healthcare)、FACS等を用いることが可能である。 When the antigen is a soluble antigen, k d (dissociation rate constant) can be used as the value of the antigen binding activity, but when the antigen is a membrane antigen, apparent k d (Apparent dissociation rate constant) is used. Dissociation rate constant) can be used. The k d (dissociation rate constant) and the apparent k d (apparent dissociation rate constant) can be measured by a method known to those skilled in the art, and for example, Biacore (GE healthcare), FACS, or the like can be used. It is possible.
なお本発明において異なるpHで抗原結合分子の抗原結合活性を測定する際は、pH以外の条件は同一とすることが好ましい。 In the present invention, when measuring the antigen-binding activity of an antigen-binding molecule at different pH, it is preferable that the conditions other than pH are the same.
抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする方法(pH依存的な結合能を付与する方法)は特に限定されず、如何なる方法により行われてもよい。例えば抗原結合分子中のアミノ酸をヒスチジンに置換する、又は抗原結合分子中にヒスチジンを挿入することによりpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする方法を挙げることができる。抗体中のアミノ酸をヒスチジンで置換することによりpH依存性の抗原結合活性を抗体に付与できることは既に知られている(FEBS Letter, 309(1), 85-88, (1992))。ヒスチジン変異(置換)又は挿入が導入される(行われる)位置は特に限定されず、変異又は挿入前と比較してpH5.8における抗原結合活性がpH7.4における抗原結合活性より弱くなる(KD(pH5.8)/KD(pH7.4)の値が大きくなる)限り、如何なる部位でもよい。例えば、抗原結合分子が抗体の場合には、抗体の可変領域などを挙げることができる。ヒスチジン変異又は挿入が導入される(行われる)数は当業者が適宜決定することができ、1箇所のみをヒスチジンで置換してもよいし、又は1箇所のみにヒスチジンを挿入してもよいし、2箇所以上の複数箇所をヒスチジンで置換してもよいし、又は2箇所以上の複数箇所にヒスチジンを挿入してもよい。又、ヒスチジン変異以外の変異(ヒスチジン以外のアミノ酸への変異)を同時に導入してもよい。さらに、ヒスチジン変異とヒスチジン挿入を同時に行ってもよい。ヒスチジンへの置換又はヒスチジンの挿入は当業者に公知のアラニンscanningのアラニンをヒスチジンに置き換えたヒスチジンscanningなどの方法によりランダムに行ってもよく、ヒスチジン変異又は挿入がランダムに導入された抗原結合分子ライブラリーの中から、変異前と比較してKD(pH5.8)/KD(pH7.4)の値が大きくなった抗原結合分子を選択してもよい。 The method of weakening the antigen-binding activity of the antigen-binding molecule at pH 5.8 to weaker than the antigen-binding activity at pH 7.4 (method of imparting pH-dependent binding ability) is not particularly limited, and any method may be used. For example, a method of replacing the amino acid in the antigen-binding molecule with histidine or inserting histidine into the antigen-binding molecule to make the antigen-binding activity at pH 5.8 weaker than the antigen-binding activity at pH 7.4 can be mentioned. It is already known that pH-dependent antigen-binding activity can be imparted to an antibody by substituting histidine for an amino acid in the antibody (FEBS Letter, 309 (1), 85-88, (1992)). The position where the histidine mutation (substitution) or insertion is introduced (performed) is not particularly limited, and the antigen-binding activity at pH 5.8 is weaker than that before the mutation or insertion (KD). Any site may be used as long as (pH 5.8) / KD (pH 7.4) increases). For example, when the antigen-binding molecule is an antibody, the variable region of the antibody can be mentioned. The number of histidine mutations or insertions introduced (performed) can be appropriately determined by those skilled in the art, and only one site may be replaced with histidine, or only one site may be inserted with histidine. , Two or more locations may be replaced with histidine, or histidine may be inserted at two or more locations. Further, a mutation other than the histidine mutation (mutation to an amino acid other than histidine) may be introduced at the same time. Furthermore, the histidine mutation and histidine insertion may be performed at the same time. Substitution with histidine or insertion of histidine may be performed randomly by a method such as histidine scanning in which alanine of alanine scanning known to those skilled in the art is replaced with histidine, and an antigen-binding molecule live in which a histidine mutation or insertion is randomly introduced. From the rally, an antigen-binding molecule having a larger KD (pH 5.8) / KD (pH 7.4) value than before the mutation may be selected.
抗原結合分子のアミノ酸をヒスチジンに置換又は抗原結合分子のアミノ酸にヒスチジンを挿入する場合、特に限定されないが、ヒスチジン置換又は挿入後の抗原結合分子のpH7.4における抗原結合活性が、ヒスチジン置換又は挿入前の抗原結合分子のpH7.4における抗原結合活性と同等であることが好ましい。ここで、ヒスチジン置換又は挿入後の抗原結合分子のpH7.4における抗原結合活性が、ヒスチジン置換又は挿入前の抗原結合分子のpH7.4における抗原結合活性と同等であるとは、ヒスチジン置換又は挿入後の抗原結合分子が、ヒスチジン置換又は挿入前の抗原結合分子が有する抗原結合活性の10%以上、好ましくは50%以上、さらに好ましくは80%以上、より好ましくは90%以上を維持していることを言う。ヒスチジン置換又は挿入により抗原結合分子の抗原結合活性が低くなった場合には、抗原結合分子中の1又は複数のアミノ酸の置換、欠失、付加及び/又は挿入などにより抗原結合活性をヒスチジン置換又は挿入前の抗原結合活性と同等にしてもよい。本発明においては、そのようなヒスチジン置換又は挿入後に1又は複数のアミノ酸の置換、欠失、付加及び/又は挿入を行うことにより結合活性が同等となった抗原結合分子も含まれる。 When the amino acid of the antigen-binding molecule is replaced with histidine or histidine is inserted into the amino acid of the antigen-binding molecule, the antigen-binding activity of the antigen-binding molecule after the histidine substitution or insertion at pH 7.4 is histidine substitution or insertion. It is preferably equivalent to the antigen-binding activity of the previous antigen-binding molecule at pH 7.4. Here, it is said that the antigen-binding activity of the antigen-binding molecule after histidine substitution or insertion at pH 7.4 is equivalent to the antigen-binding activity of the antigen-binding molecule before histidine substitution or insertion at pH 7.4. The subsequent antigen-binding molecule maintains 10% or more, preferably 50% or more, more preferably 80% or more, and more preferably 90% or more of the antigen-binding activity of the antigen-binding molecule before histidine substitution or insertion. Say that. When the antigen-binding activity of an antigen-binding molecule is reduced by histidine substitution or insertion, the antigen-binding activity is replaced by histidine substitution or insertion by substitution, deletion, addition and / or insertion of one or more amino acids in the antigen-binding molecule. It may be equivalent to the antigen-binding activity before insertion. The present invention also includes antigen-binding molecules having equivalent binding activity by substituting, deleting, adding and / or inserting one or more amino acids after such histidine substitution or insertion.
又、抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする他の方法として、抗原結合分子中のアミノ酸を非天然型アミノ酸に置換又は抗原結合分子中のアミノ酸に非天然型アミノ酸を挿入する方法を挙げることができる。非天然アミノ酸は人為的にpKaをコントロールすることができることが知られている(Angew. Chem. Int. Ed. 2005, 44, 34、Chem Soc Rev. 2004 Sep 10;33(7):422-30.、Amino Acids. 1999;16(3-4):345-79.)。従って、本発明においては上述のヒスチジンの代わりに非天然型アミノ酸を用いることが可能である。又、上述のヒスチジン置換及び/又は挿入と、非天然型アミノ酸の置換及び/又は挿入は、同時に行ってもよい。本発明で用いられる非天然型アミノ酸は如何なる非天然型アミノ酸でもよく、当業者に公知の非天然型アミノ酸等を用いることが可能である。
In addition, as another method of weakening the antigen-binding activity of the antigen-binding molecule at pH 5.8 to weaker than the antigen-binding activity at pH 7.4, the amino acid in the antigen-binding molecule is replaced with an unnatural amino acid or an amino acid in the antigen-binding molecule. A method of inserting an unnatural antigen can be mentioned. Unnatural amino acids are known to be able to artificially control pKa (Angew. Chem. Int. Ed. 2005, 44, 34, Chem Soc Rev. 2004
さらに、抗原結合分子が抗体定常領域を含む物質である場合、抗原結合分子のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする他の方法として、抗原結合分子に含まれる抗体定常領域を改変する方法を挙げることができる。このような抗体定常領域の改変の具体例としては、例えば実施例に記載の定常領域に置換する方法を挙げることが出来る。 Furthermore, when the antigen-binding molecule is a substance containing an antibody constant region, the antibody contained in the antigen-binding molecule is another method of weakening the antigen-binding activity of the antigen-binding molecule at pH 5.8 to weaker than the antigen-binding activity at pH 7.4. A method of modifying the constant region can be mentioned. Specific examples of such modification of the antibody constant region include a method of substituting with the constant region described in Examples.
また、抗体定常領域の改変方法としては、例えば、定常領域のアイソタイプ(IgG1、IgG2、IgG3、IgG4)を複数検討し、pH5.8における抗原結合活性が低下する(pH5.8における解離速度が速くなる)アイソタイプを選択する方法が挙げられる。さらに野生型アイソタイプのアミノ酸配列(野生型IgG1、IgG2、IgG3、IgG4アミノ酸配列)にアミノ酸置換を導入することで、pH5.8における抗原結合活性を低下させる(pH5.8における解離速度が速くする)方法が挙げられる。アイソタイプ(IgG1、IgG2、IgG3、IgG4)によって抗体定常領域のヒンジ領域の配列が大きく異なり、ヒンジ領域のアミノ酸配列の違いは抗原結合活性に大きく影響を与えるため、抗原やエピトープの種類によって適切なアイソタイプを選択することでpH5.8における抗原結合活性が低下する(pH5.8における解離速度が速くする)アイソタイプを選択することが可能である。また、ヒンジ領域のアミノ酸配列の違いは抗原結合活性に大きく影響を与えることから、野生型アイソタイプのアミノ酸配列のアミノ酸置換箇所としては、ヒンジ領域が望ましいと考えられる。 In addition, as a method for modifying the antibody constant region, for example, a plurality of isotypes of the constant region (IgG1, IgG2, IgG3, IgG4) are examined, and the antigen-binding activity at pH 5.8 decreases (dissociation rate at pH 5.8 is high). There is a method of selecting an isotype. Furthermore, by introducing amino acid substitutions into the wild-type isotype amino acid sequences (wild-type IgG1, IgG2, IgG3, IgG4 amino acid sequences), the antigen-binding activity at pH 5.8 is reduced (the dissociation rate at pH 5.8 is increased). The method can be mentioned. The sequence of the hinge region of the antibody constant region differs greatly depending on the isotype (IgG1, IgG2, IgG3, IgG4), and the difference in the amino acid sequence of the hinge region greatly affects the antigen-binding activity. Therefore, the appropriate isotype depends on the type of antigen or epitope. It is possible to select an isotype in which the antigen-binding activity at pH 5.8 decreases (the dissociation rate at pH 5.8 increases). In addition, since the difference in the amino acid sequence of the hinge region greatly affects the antigen-binding activity, it is considered that the hinge region is desirable as the amino acid substitution site of the wild-type isotype amino acid sequence.
上述の方法等により抗原結合物質のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする(KD(pH5.8)/KD(pH7.4)の値を大きくする)場合、特に限定されないが、KD(pH5.8)/KD(pH7.4)の値が基の抗体と比較して通常、2倍以上、好ましくは5倍以上、さらに好ましくは10倍以上となっていることが好ましい。 Especially when the antigen-binding activity of the antigen-binding substance at pH 5.8 is weaker than the antigen-binding activity at pH 7.4 (the value of KD (pH 5.8) / KD (pH 7.4) is increased) by the above method or the like. Although not limited, the value of KD (pH 5.8) / KD (pH 7.4) is usually 2 times or more, preferably 5 times or more, and more preferably 10 times or more that of the base antibody. Is preferable.
本発明において「薬物動態が向上する」とは、抗原結合分子がヒト、マウス、ラット、サル、ウサギ、イヌなどの動物に投与されてから、血漿中から消失するまで(例えば、細胞内で分解される等して抗原結合分子が血漿中に戻ることが不可能な状態になるまで)の時間が長くなることのみならず、抗原結合分子が投与されてから血漿中から消失するまでの間に抗原に結合可能な状態(例えば、抗原結合分子が抗原に結合していない状態)で血漿中に滞留する時間が長くなることも含む。抗原結合分子が血漿中に存在していても、その抗原結合分子にすでに抗原が結合している場合は、その抗原結合分子は新たな抗原に結合できない。そのため抗原結合分子が抗原に結合していない時間が長くなれば、新たな抗原に結合できる時間が長くなり(新たな抗原に結合できる機会が多くなり)、生体内で抗原が抗原結合分子に結合していない時間を減少させることができる(言い換えれば、抗原に抗原結合分子が結合している時間を長くすることができる)。例えば血漿中などの生体内に存在する抗原(抗原結合分子に結合している分子と抗原結合分子に結合していない抗原の総量)に対する、抗原結合分子に結合している抗原の割合は、通常、抗原結合分子投与後、一定時間が経過すると減少していく。しかし、抗原結合分子が抗原に結合可能な状態で滞留する時間が長くなれば、その減少を抑制(例えば、減少の度合いを少なくする、等)することが可能となり、結果として抗体投与から一定期間経過した後の生体内に存在する抗原に対する、抗原結合分子に結合している抗原の割合が高くなる。 In the present invention, "improved pharmacokinetics" means that an antigen-binding molecule is administered to animals such as humans, mice, rats, monkeys, rabbits, and dogs until it disappears from plasma (for example, intracellular degradation). Not only does it take longer to make it impossible for the antigen-binding molecule to return to the plasma, but also between the time the antigen-binding molecule is administered and the time it disappears from the plasma. It also includes a longer residence time in plasma in a state where it can bind to an antigen (for example, a state in which an antigen-binding molecule is not bound to an antigen). Even if an antigen-binding molecule is present in plasma, if the antigen is already bound to the antigen-binding molecule, the antigen-binding molecule cannot bind to a new antigen. Therefore, the longer the antigen-binding molecule is not bound to the antigen, the longer it can bind to the new antigen (more chances to bind to the new antigen), and the antigen binds to the antigen-binding molecule in vivo. It is possible to reduce the amount of time that the antigen-binding molecule is not attached (in other words, the amount of time that the antigen-binding molecule is bound to the antigen can be increased). For example, the ratio of the antigen bound to the antigen-binding molecule to the antigen existing in the living body such as in plasma (the total amount of the molecule bound to the antigen-binding molecule and the antigen not bound to the antigen-binding molecule) is usually , It decreases after a certain period of time after administration of the antigen-binding molecule. However, if the antigen-binding molecule stays in a state where it can bind to the antigen for a long time, it becomes possible to suppress the decrease (for example, reduce the degree of decrease, etc.), and as a result, for a certain period from the antibody administration. The ratio of the antigen bound to the antigen-binding molecule to the antigen existing in the living body after the lapse of time increases.
つまり、本発明の「薬物動態の向上」は、必ずしも抗原結合分子が投与されてから抗原結合分子が消失するまでの時間が延長される(長くなる)必要はない。たとえ抗原結合分子が投与されてから消失するまでの時間に変化がなくても、抗原結合分子が抗原に結合できる状態(例えば、抗原結合分子が抗原に結合していない状態)で血漿中に滞留している時間が長くなっている場合、生体内の抗原が抗原結合分子に結合していない時間が減少している(言い換えれば、抗原に抗原結合分子が結合している時間が長くなっている)場合、又は生体内に存在する抗原に対する抗原結合分子に結合している抗原の割合が高くなっている場合のいずれの場合も、本発明の「薬物動態の向上」に含まれる。従って、本発明の「薬物動態の向上」には少なくとも以下の(1)〜(4)が含まれる。
(1)抗原結合分子が投与されてから、抗原結合分子が血漿中から消失するまでの時間の延長。
(2)抗原結合分子が投与されてから、抗原結合分子が抗原に結合可能な状態で血漿中に存在する時間の延長。
(3)抗原結合分子が投与されてから、生体内の抗原が抗原結合分子と結合していない時間の減少(生体内の抗原に抗原結合分子が結合している時間の延長)。
(4)生体内に存在する抗原に対する抗原結合分子に結合した抗原の割合の上昇。
That is, the "improvement of pharmacokinetics" of the present invention does not necessarily mean that the time from the administration of the antigen-binding molecule to the disappearance of the antigen-binding molecule does not have to be extended (longer). Even if there is no change in the time from administration of the antigen-binding molecule to its disappearance, the antigen-binding molecule stays in the plasma in a state where it can bind to the antigen (for example, a state in which the antigen-binding molecule is not bound to the antigen). When the time spent is long, the time when the antigen in the living body is not bound to the antigen-binding molecule is reduced (in other words, the time when the antigen-binding molecule is bound to the antigen is long. ), Or when the ratio of the antigen bound to the antigen-binding molecule to the antigen existing in the living body is high, it is included in the "improvement of pharmacokinetics" of the present invention. Therefore, the "improvement of pharmacokinetics" of the present invention includes at least the following (1) to (4).
(1) Extension of the time from administration of the antigen-binding molecule to the disappearance of the antigen-binding molecule from plasma.
(2) Prolongation of the time that the antigen-binding molecule is present in plasma in a state where it can bind to the antigen after the antigen-binding molecule is administered.
(3) Decrease in the time that the antigen in the body is not bound to the antigen-binding molecule after the administration of the antigen-binding molecule (extension of the time that the antigen-binding molecule is bound to the antigen in the body).
(4) Increase in the ratio of antigen bound to the antigen-binding molecule to the antigen existing in the living body.
又、抗原が血漿中に存在する可溶型抗原の場合、抗原結合分子の薬物動態(血漿中からの消失速度)が同等であっても、抗原結合分子が結合している抗原の消失が早くなることがある。これは抗原の薬物動態を低下させる(血漿中からの消失を早くする)ことで、抗原に対する相対的な抗原結合分子の薬物動態が向上していることにつながり、すなわち、抗原結合分子が抗原に結合可能な状態で血漿中に存在する時間の延長につながる。従って、本発明の抗原結合分子の「薬物動態の向上」の一態様として、抗原結合分子が投与されてから、可溶型抗原が血漿中から消失する速さ(抗原結合分子の血漿中抗原消失能)の上昇も含まれる。 Further, in the case of a soluble antigen in which the antigen is present in plasma, the antigen to which the antigen-binding molecule is bound disappears quickly even if the pharmacokinetics of the antigen-binding molecule (disappearance rate from plasma) are the same. May become. This reduces the pharmacokinetics of the antigen (accelerates its disappearance from plasma), leading to improved pharmacokinetics of the antigen-binding molecule relative to the antigen, that is, the antigen-binding molecule becomes an antigen. It leads to an extension of the time that it is present in plasma in a bindable state. Therefore, as one aspect of "improvement of pharmacokinetics" of the antigen-binding molecule of the present invention, the rate at which the soluble antigen disappears from plasma after the antigen-binding molecule is administered (antigen disappearance of the antigen-binding molecule in plasma). The increase in ability) is also included.
本発明において、1分子の抗原結合分子が複数の抗原に結合したかどうかは、抗原が膜型抗原の場合、抗原結合分子の薬物動態が向上したかどうかで判断することが可能である。「薬物動態が向上した」か否かは、以下のようにして判断することが可能である。例えば抗原結合分子が投与されてから抗原結合分子が消失するまでの時間が延長されたか否かは、抗原結合分子の血漿中半減期、平均血漿中滞留時間、血漿中クリアランス等のいずれかのパラメーター(ファーマコキネティクス 演習による理解(南山堂))を測定することにより判断することが可能である。例えば、抗原結合分子をマウス、ラット、サル、ウサギ、イヌ、ヒトなどに投与した場合、血漿中半減期が長くなった又は平均血漿中滞留時間が長くなった場合等には抗原結合分子の薬物動態が向上したと言える。これらのパラメーターは当業者に公知の方法により測定することが可能であり、例えば、薬物動態解析ソフトWinNonlin(Pharsight)を用いて、付属の手順書に従いNoncompartmental解析することによって適宜評価することができる。 In the present invention, whether or not one antigen-binding molecule is bound to a plurality of antigens can be determined by whether or not the pharmacokinetics of the antigen-binding molecule is improved when the antigen is a membrane-type antigen. Whether or not "pharmacokinetics has improved" can be determined as follows. For example, whether or not the time from administration of the antigen-binding molecule to the disappearance of the antigen-binding molecule is extended is one of parameters such as plasma half-life, average plasma residence time, and plasma clearance of the antigen-binding molecule. It is possible to make a judgment by measuring (Understanding by Pharmacokinetic Exercise (Nanzan-do)). For example, when an antigen-binding molecule is administered to mice, rats, monkeys, rabbits, dogs, humans, etc., the drug of the antigen-binding molecule has a long half-life in plasma or a long residence time in plasma. It can be said that the dynamics have improved. These parameters can be measured by a method known to those skilled in the art, and can be appropriately evaluated by performing non-compartmental analysis according to the attached procedure manual using, for example, pharmacokinetic analysis software WinNonlin (Pharsight).
又、抗原結合分子が投与されてから消失するまでの間に抗原に結合可能な状態で血漿中に存在する時間が延長されたか否かは、抗原に結合していない抗原結合分子の血漿中濃度を測定し、抗原に結合していない抗原結合分子の血漿中半減期、平均血漿中滞留時間、血漿中クリアランス等のいずれかのパラメーターを測定することにより判断することが可能である。抗原に結合していない抗原結合分子の血漿中濃度の測定は当業者公知の方法で実施することが可能であり、例えば、Clin Pharmacol. 2008 Apr;48(4):406-17において測定されている。 In addition, whether or not the time that the antigen-binding molecule is present in the plasma in a state where it can bind to the antigen is extended between the time when the antigen-binding molecule is administered and the time when it disappears depends on the plasma concentration of the antigen-binding molecule that is not bound to the antigen. Can be determined by measuring any of the parameters such as the half-life in plasma, the average residence time in plasma, and the clearance in plasma of the antigen-binding molecule that is not bound to the antigen. Measurement of plasma concentration of antigen-binding molecules that are not bound to the antigen can be performed by methods known to those skilled in the art, for example, as measured in Clin Pharmacol. 2008 Apr; 48 (4): 406-17. There is.
又、抗原結合分子が投与されてから、生体内の抗原が抗原結合分子に結合していない時間が減少した(抗原に抗原結合分子が結合している時間が長くなった)か否かは、抗原結合分子が結合していない非結合型の抗原の血漿中濃度を測定し、非結合型の抗原の血漿中濃度、あるいは、総抗原量に対する非結合型の抗原量の割合が低く維持されている期間をもとに判断することが可能である。非結合型の抗原の血漿中濃度、あるいは、総抗原量に対する非結合型の抗原の抗原量の割合の測定は当業者公知の方法で実施することが可能であり、例えば、Pharm Res. 2006 Jan;23(1):95-103において測定されている。また、抗原が何らかの機能を生体内で示す場合、抗原が抗原の機能を中和する抗原結合分子(アンタゴニスト分子)によって結合されているかどうかは、その抗原の機能が中和されているかどうかで評価することも可能である。抗原の機能が中和されているかどうかは、抗原の機能を反映する何らかの生体内のマーカーを測定することで評価することが可能である。抗原が抗原の機能を活性化する抗原結合分子(アゴニスト分子)によって結合されているかどうかは、抗原の機能を反映する何らかの生体内のマーカーを測定することで評価することが可能である。 In addition, whether or not the time during which the antigen in the living body is not bound to the antigen-binding molecule has decreased (the time during which the antigen-binding molecule has been bound to the antigen has increased) since the antigen-binding molecule was administered is determined. The plasma concentration of the unbound antigen to which the antigen-binding molecule is not bound is measured, and the plasma concentration of the unbound antigen or the ratio of the unbound antigen amount to the total antigen amount is maintained low. It is possible to make a judgment based on the period of time. The plasma concentration of the unbound antigen or the ratio of the antigen amount of the unbound antigen to the total antigen amount can be measured by a method known to those skilled in the art, for example, Pharm Res. 2006 Jan. 23 (1): Measured at 95-103. In addition, when an antigen exhibits some function in vivo, whether or not the antigen is bound by an antigen-binding molecule (antagonist molecule) that neutralizes the function of the antigen is evaluated by whether or not the function of the antigen is neutralized. It is also possible to do. Whether or not the function of the antigen is neutralized can be evaluated by measuring some in vivo marker that reflects the function of the antigen. Whether or not an antigen is bound by an antigen-binding molecule (agonist molecule) that activates the function of the antigen can be evaluated by measuring some in vivo marker that reflects the function of the antigen.
非結合型の抗原の血漿中濃度の測定、総抗原量に対する非結合型の抗原の抗原量の割合の測定、生体内マーカーの測定などの測定は特に限定されないが、抗原結合物質が投与されてから一定時間が経過した後に行われることが好ましい。本発明において抗原結合物質が投与されてから一定時間が経過した後とは、特に限定されず、投与された抗原結合物質の性質等により当業者が適時決定することが可能であるが、例えば抗原結合物質を投与してから1日経過後、抗原結合物質を投与してから3日経過後、抗原結合物質を投与してから7日経過後、抗原結合物質を投与してから14日経過後、抗原結合物質を投与してから28日経過後などを挙げることができる。
Measurements such as measurement of plasma concentration of unbound antigen, measurement of the ratio of antigen amount of unbound antigen to total antigen amount, measurement of in vivo markers, etc. are not particularly limited, but the antigen-binding substance is administered. It is preferable that this is performed after a certain period of time has elapsed. In the present invention, the time after a certain period of time has passed since the antigen-binding substance was administered is not particularly limited, and can be timely determined by a person skilled in the art depending on the nature of the administered antigen-binding substance and the like. 1 day after the administration of the binding substance, 3 days after the administration of the antigen-binding substance, 7 days after the administration of the antigen-binding substance, 14 days after the administration of the antigen-binding substance, the antigen-binding
本発明においては、ヒトにおける薬物動態が向上することが好ましい。ヒトでの血漿中滞留性を測定することが困難である場合には、マウス(例えば、正常マウス、ヒト抗原発現トランスジェニックマウス、ヒトFcRn発現トランスジェニックマウス、等)やサル(例えば、カニクイザルなど)での血漿中滞留性を基に、ヒトでの血漿中滞留性を予測することができる。 In the present invention, it is preferable that the pharmacokinetics in humans is improved. If it is difficult to measure plasma retention in humans, mice (eg, normal mice, human antigen-expressing transgenic mice, human FcRn-expressing transgenic mice, etc.) and monkeys (eg, cynomolgus monkeys, etc.) The plasma retention in humans can be predicted based on the plasma retention in humans.
血漿中滞留性の測定方法は、特に限定されないが、例えば実施例に記載の方法に従って行うことができる。 The method for measuring plasma retention is not particularly limited, but can be carried out, for example, according to the method described in Examples.
抗原結合分子が抗原に複数回結合可能であるかどうかは、血漿中と同じ中性条件下で抗原結合分子に結合した抗原がエンドソーム内と同じ酸性条件下で解離し、再び中性条件下でどれだけの抗原に結合できるかどうかを測定することによって評価することが可能である。具体的には、Biacoreのような抗原結合分子−抗原反応を評価する機器を用いて、中性条件下で抗原結合分子−抗原複合体を作らせ、その後一定時間酸性条件下に曝らした後に、再び中性条件下において抗原結合分子が抗原に結合できるかどうかを測定することで評価可能である。改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子の抗原結合量が2倍向上した場合、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子は結合回数が2倍向上していると言える。また、抗原が膜型抗原であって抗原に結合した抗原結合分子が抗原を介して取り込まれライソソームで分解されることで血漿中から消失する場合、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子の薬物動態あるいは抗原への結合期間がどれだけ向上したかどうかを評価することによって、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子の結合回数が増大しているかどうかを評価することが可能である。例えば、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子の抗原への結合期間が2倍向上した場合、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子は結合回数が2倍向上していると言える。また、抗原結合分子が結合していない非結合型の抗原の血漿中濃度を測定し、非結合型の抗原の血漿中濃度、あるいは、総抗原量に対する非結合型の抗原の抗原量の割合、が低く維持されている時間が2倍延長した場合、改変前の抗原結合分子と比較してpH依存的結合能を付与した抗原結合分子は結合回数が2倍向上していると言える。 Whether or not an antigen-binding molecule can bind to an antigen multiple times depends on whether the antigen bound to the antigen-binding molecule dissociates under the same acidic conditions as in endosome under the same neutral conditions as in plasma and again under neutral conditions. It can be evaluated by measuring how much antigen can be bound. Specifically, an antigen-binding molecule-antigen complex such as Biacore is used to form an antigen-binding molecule-antigen complex under neutral conditions, and then exposed to acidic conditions for a certain period of time. Again, it can be evaluated by measuring whether the antigen-binding molecule can bind to the antigen under neutral conditions. When the antigen-binding amount of the antigen-binding molecule imparted with the pH-dependent binding ability was doubled as compared with the antigen-binding molecule before modification, the pH-dependent binding ability was imparted as compared with the antigen-binding molecule before modification. It can be said that the number of bindings of the antigen-binding molecule is doubled. In addition, when the antigen is a membrane-type antigen and the antigen-binding molecule bound to the antigen is taken up via the antigen and decomposed by the lysosome to disappear from the plasma, it is pH-dependent as compared with the antigen-binding molecule before modification. By evaluating the pharmacokinetics of the antigen-binding molecule imparted with the target-binding ability or how much the binding period to the antigen is improved, the antigen imparted with the pH-dependent binding ability as compared with the antigen-binding molecule before modification. It is possible to evaluate whether or not the number of bindings of the binding molecule is increased. For example, when the binding period of an antigen-binding molecule imparted with pH-dependent binding ability to an antigen is doubled as compared with the antigen-binding molecule before modification, pH-dependent binding is performed as compared with the antigen-binding molecule before modification. It can be said that the antigen-binding molecule to which the function has been imparted has twice the number of bindings. In addition, the plasma concentration of the unbound antigen to which the antigen-binding molecule is not bound is measured, and the plasma concentration of the unbound antigen or the ratio of the antigen amount of the unbound antigen to the total antigen amount, It can be said that the number of bindings of the antigen-binding molecule imparted with the pH-dependent binding ability is doubled as compared with the antigen-binding molecule before modification when the time during which the value is kept low is extended twice.
又、抗原が可溶型抗原の場合、血漿中の中性条件下で抗原結合分子に結合した抗原がエンドソーム内で解離して抗原結合分子が血漿中に戻れば、抗原結合分子は再び血漿中の中性条件下で抗原に結合できるため、エンドソーム内の酸性条件下で抗原を解離する性質を有する抗原結合分子は抗原に複数回結合可能である。抗原結合分子に結合した抗原がエンドソーム内で解離しない場合(抗原は抗原結合分子に結合したまま血漿中に戻る)と比較して、抗原結合分子に結合した抗原がエンドソーム内で解離する場合は、抗原はライソソームに運ばれ分解されるため抗原の血漿中からの消失速度は増加する。すなわち、血漿中から抗原が消失する速度を指標として抗原結合分子が抗原に複数回結合可能であるか否かを判断することも可能である。抗原の血漿中からの消失速度の測定は、例えば、抗原(例えば、膜抗原)と抗原結合分子を生体内に投与し、投与後の血漿中の抗原濃度を測定することにより行うことも可能である。また、抗原(例えば、膜抗原)が生体内で産生(分泌)される場合、抗原の血漿中からの消失速度が増加していれば血漿中抗原濃度は低下することから、血漿中抗原濃度を指標として抗原結合分子が抗原に複数回結合可能であるか否かを判断することも可能である。 When the antigen is a soluble antigen, if the antigen bound to the antigen-binding molecule dissociates in the endosome under neutral conditions in the plasma and the antigen-binding molecule returns to the plasma, the antigen-binding molecule is again in the plasma. Since it can bind to the antigen under neutral conditions, the antigen-binding molecule having the property of dissociating the antigen under acidic conditions in the endosome can bind to the antigen multiple times. When the antigen bound to the antigen-binding molecule dissociates in the endosome, compared to the case where the antigen bound to the antigen-binding molecule does not dissociate in the endosome (the antigen returns to the plasma while bound to the antigen-binding molecule). Since the antigen is transported to the lysosome and degraded, the rate of elimination of the antigen from the plasma increases. That is, it is also possible to determine whether or not the antigen-binding molecule can bind to the antigen a plurality of times using the rate at which the antigen disappears from plasma as an index. The rate of elimination of an antigen from plasma can be measured, for example, by administering an antigen (for example, a membrane antigen) and an antigen-binding molecule in vivo and measuring the antigen concentration in plasma after administration. is there. In addition, when an antigen (for example, a membrane antigen) is produced (secreted) in vivo, the plasma antigen concentration decreases as the rate of elimination of the antigen from plasma increases. As an index, it is also possible to determine whether or not the antigen-binding molecule can bind to the antigen multiple times.
本発明において、「抗原結合分子の抗原への結合回数を増やす」とは、抗原結合分子がヒト、マウス、サルなどに投与された際に、抗原結合分子が抗原に結合し、細胞内に取り込まれる工程を1回とし、この工程が増えることを意味する。つまり本発明において、「抗原結合分子が抗原に2回結合する」とは、抗原結合分子が抗原に結合した状態で細胞内に取り込まれた後に、抗原を解離した状態で細胞外に放出され、放出された抗原結合分子が再度抗原に結合し、細胞内に取り込まれることを意味する。 In the present invention, "increasing the number of times an antigen-binding molecule binds to an antigen" means that when the antigen-binding molecule is administered to humans, mice, monkeys, etc., the antigen-binding molecule binds to the antigen and is taken up into cells. This means that the number of steps to be performed is one, and this step is increased. That is, in the present invention, "the antigen-binding molecule binds to the antigen twice" means that the antigen-binding molecule is taken up into the cell in a state of being bound to the antigen and then released extracellularly in a state of dissociating the antigen. It means that the released antigen-binding molecule binds to the antigen again and is taken up into the cell.
抗原結合分子が細胞に取り込まれる際には、抗原結合分子は1つの抗原を結合した状態で取り込まれてもよいし、2つ若しくはそれ以上の抗原を結合した状態で取り込まれてもよい。 When an antigen-binding molecule is incorporated into a cell, the antigen-binding molecule may be incorporated in a state in which one antigen is bound, or may be incorporated in a state in which two or more antigens are bound.
本発明において、「抗原結合分子の抗原への結合回数が増える」とは、全ての抗原結合分子の抗原結合回数が増える必要はなく、例えば、抗原結合分子組成物に含まれる抗原結合分子のうち、2回以上抗原に結合する抗原結合分子の割合が上昇することや、抗原結合分子組成物に含まれる抗原結合分子の結合回数の平均が上昇すること等でもよい。 In the present invention, "the number of times an antigen-binding molecule binds to an antigen increases" means that the number of times all antigen-binding molecules bind to an antigen does not have to increase. For example, among the antigen-binding molecules contained in the antigen-binding molecule composition. , The ratio of the antigen-binding molecule that binds to the antigen twice or more may be increased, or the average number of bindings of the antigen-binding molecule contained in the antigen-binding molecule composition may be increased.
本発明においては、抗原結合分子をヒトに投与した際の抗原結合分子の抗原への結合回数が増えることが好ましいが、ヒトでの抗原結合回数を測定することが困難である場合には、in vitroでの測定結果、マウス(例えば、抗原発現トランスジェニックマウス、ヒトFcRn発現トランスジェニックマウス、等)やサル(例えば、カニクイザルなど)などでの測定結果を基にヒトでの抗原結合回数を予想してもよい。 In the present invention, it is preferable that the number of times the antigen-binding molecule binds to the antigen when the antigen-binding molecule is administered to humans increases, but when it is difficult to measure the number of times of antigen binding in humans, in The number of antigen bindings in humans is predicted based on the measurement results in vitro and the measurement results in mice (for example, antigen-expressing transgenic mice, human FcRn-expressing transgenic mice, etc.) and monkeys (for example, crab monkeys). You may.
本発明においては、抗原結合分子が2回以上抗原に結合することが好ましく、例えば、抗原結合分子組成物に含まれる抗原結合分子の少なくとも10%以上、好ましくは30%以上、さらに好ましくは50%以上、より好ましくは80%以上(例えば、90%以上、95%以上など)の抗原結合分子が2回以上抗原に結合することが好ましい。 In the present invention, the antigen-binding molecule preferably binds to the antigen twice or more, for example, at least 10% or more, preferably 30% or more, still more preferably 50% of the antigen-binding molecule contained in the antigen-binding molecule composition. As mentioned above, it is more preferable that 80% or more (for example, 90% or more, 95% or more, etc.) of the antigen-binding molecule binds to the antigen twice or more.
本発明において、「抗原結合分子が結合可能な抗原の数を増やす」とは、抗原結合分子がヒト、マウス、サルなどの動物に投与されてから、細胞内のライソソームで分解されるまでの間に抗原結合分子が結合できる抗原の数を増やすことを意味する。 In the present invention, "increasing the number of antigens to which an antigen-binding molecule can bind" means that the antigen-binding molecule is administered to animals such as humans, mice, and monkeys until it is degraded by intracellular lysosomes. This means increasing the number of antigens to which the antigen-binding molecule can bind.
通常、IgGなどの抗体は2つの結合部位を有するので、1つの抗体は最大で2つの抗原に結合し、抗原に結合した抗体は細胞内に取り込まれ、ライソソームで抗原とともに分解される。従って、通常、IgGなどの抗体は最大で2つの抗原に結合することが可能である。本発明の方法により抗体などの抗原結合分子のエンドソーム内でのpHにおける抗原結合活性を血漿中でのpHにおける抗原結合活性よりも弱くすることにより、細胞内に取り込まれた抗体などの抗原結合分子は、細胞内で抗原を解離し、再び細胞外へと放出されて抗原に結合することが可能となる。つまり、本発明の方法により、抗原結合分子の抗原結合部位の数よりも多い数の抗原に結合することが可能となる。具体的には、例えば2つの結合部位を有するIgGの場合、本発明の方法を用いることにより、抗体が投与されてから抗体が分解されるまでの間に3つ以上、好ましくは4つ以上の抗原に結合することが可能となる。例えば、抗体が中和抗体の場合、「抗原結合分子が結合可能な抗原の数を増やす」とは、抗原結合分子が中和可能な抗原の数を増やす、ということもできる。従って、抗体が中和抗体の場合には、「結合」を「中和」と置き換えることも可能である。 Normally, an antibody such as IgG has two binding sites, so that one antibody binds to a maximum of two antigens, and the antibody bound to the antigen is taken up into cells and degraded together with the antigen in the lysosome. Therefore, antibodies such as IgG are usually capable of binding up to two antigens. By the method of the present invention, the antigen-binding activity of an antigen-binding molecule such as an antibody at pH in endosome is weaker than the antigen-binding activity at pH in plasma, so that the antigen-binding molecule such as an antibody incorporated into cells is used. Dissociates the antigen inside the cell and is released to the outside of the cell again so that it can bind to the antigen. That is, according to the method of the present invention, it is possible to bind to a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule. Specifically, for example, in the case of IgG having two binding sites, by using the method of the present invention, three or more, preferably four or more, are used between the time when the antibody is administered and the time when the antibody is degraded. It becomes possible to bind to an antigen. For example, when the antibody is a neutralizing antibody, "increasing the number of antigens to which the antigen-binding molecule can bind" can also mean increasing the number of antigens to which the antigen-binding molecule can neutralize. Therefore, when the antibody is a neutralizing antibody, it is possible to replace "binding" with "neutralizing".
本発明において、「抗原結合分子が結合可能な抗原の数を増やす」とは、全ての抗原結合分子において結合可能な抗原の数が増える必要はなく、例えば、抗原結合分子組成物に含まれる抗原結合分子の結合可能な抗原の数の平均が増えることでもよいし、抗原結合分子の抗原結合部位の数よりも多い抗原に結合することができる抗原結合分子の割合が上昇することなどでもよい。 In the present invention, "increasing the number of antigens to which an antigen-binding molecule can bind" does not mean that the number of antigens to which an antigen-binding molecule can bind need to increase. For example, an antigen contained in an antigen-binding molecular composition. The average number of antigens to which the binding molecule can bind may increase, or the proportion of antigen-binding molecules capable of binding to more antigens than the number of antigen-binding sites of the antigen-binding molecule may increase.
本発明においては、抗原結合分子をヒトに投与した際に抗原結合分子が結合可能な抗原の数が増えることが好ましいが、ヒトでの数を測定することが困難である場合には、in vitroでの測定結果、マウス(例えば、抗原発現トランスジェニックマウス、ヒトFcRn発現トランスジェニックマウス、等)やサル(例えば、カニクイザルなど)などでの測定結果を基にヒトでの結合可能な抗原の数を予想してもよい。一般的に、抗体が中和抗体の場合、上述の抗原結合分子の抗原への結合回数は、抗原結合分子が中和可能な抗原の数と相関すると考えられる為、抗原結合分子が中和可能な抗原の数の測定は、上述の抗原結合分子の抗原への結合回数の測定と同様にして行うことが可能である。 In the present invention, it is preferable that the number of antigens to which the antigen-binding molecule can bind increases when the antigen-binding molecule is administered to humans, but when it is difficult to measure the number in humans, in vitro. Based on the measurement results in mice (eg, antigen-expressing transgenic mice, human FcRn-expressing transgenic mice, etc.) and monkeys (eg, crab monkeys, etc.), the number of antigens that can be bound in humans is determined. You may expect it. Generally, when the antibody is a neutralizing antibody, the number of times the above-mentioned antigen-binding molecule binds to an antigen is considered to correlate with the number of antigens that the antigen-binding molecule can neutralize, so that the antigen-binding molecule can be neutralized. The number of various antigens can be measured in the same manner as the above-mentioned measurement of the number of times an antigen-binding molecule binds to an antigen.
又、本発明は、酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性より低い抗原結合分子を投与することにより、体内で抗原結合分子を2回以上抗原に結合させる方法を提供する。 The present invention also provides a method for binding an antigen-binding molecule to an antigen more than once in the body by administering an antigen-binding molecule whose antigen-binding activity at acidic pH is lower than that at neutral pH.
又、本発明は、中和活性を有する抗原結合分子において、酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性より低い抗原結合分子を投与することにより、抗原結合分子の抗原結合部位の数よりも多い数の抗原を中和する方法に関する。好ましくは、酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性より低いIgGを投与することにより、3つ以上、好ましくは4つ以上の抗原を中和する方法に関する。 Further, in the present invention, in an antigen-binding molecule having neutralizing activity, the number of antigen-binding sites of the antigen-binding molecule is increased by administering an antigen-binding molecule whose antigen-binding activity at acidic pH is lower than that at neutral pH. It relates to a method of neutralizing a larger number of antigens. Preferably, the present invention relates to a method for neutralizing three or more, preferably four or more antigens by administering IgG having an antigen-binding activity at an acidic pH lower than that at a neutral pH.
さらに、本発明は抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法に関する。本発明において抗原が抗原結合分子から解離する箇所は細胞内であれば如何なる箇所でもよいが、好ましくは早期エンドソーム内である。本発明において、「細胞外で抗原結合分子に結合した抗原が細胞内で抗原結合分子から解離する」とは、抗原結合分子に結合して細胞内に取り込まれた抗原全てが細胞内で抗原結合分子から解離する必要はなく、細胞内で抗原結合分子から解離する抗原の割合が、抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能を低くする前と比較して高くなっていればよい。 Furthermore, the present invention is a method for dissociating an antigen bound to an antigen-binding molecule extracellularly from the antigen-binding molecule intracellularly by making the antigen-binding ability of the antigen-binding molecule weaker than the antigen-binding ability at neutral pH. Regarding. In the present invention, the site where the antigen dissociates from the antigen-binding molecule may be any location in the cell, but is preferably in the early endosome. In the present invention, "an antigen bound to an antigen-binding molecule outside the cell dissociates from the antigen-binding molecule inside the cell" means that all the antigens bound to the antigen-binding molecule and taken up into the cell are antigen-bound inside the cell. It is not necessary to dissociate from the molecule, and the proportion of antigens that dissociate from the antigen-binding molecule in the cell is higher than before the antigen-binding ability of the antigen-binding molecule at acidic pH was reduced to that at neutral pH. You just have to.
さらに、本発明は抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、細胞内での抗原に結合していない抗原結合分子とFcRnの結合を促進する方法に関する。通常、FcRnはエンドソーム内で抗原結合分子と結合するが、抗原結合分子が膜型抗原に結合している場合はFcRnに結合することが出来ないと考えられるので、本発明の好ましい態様として、抗原が膜型抗原の場合、抗原結合分子のエンドソーム内でのpH(酸性pH)における抗原結合能を血漿中でのpH(中性pH)における抗原結合能よりも弱くすることにより、エンドソーム内での抗原結合分子の抗原からの解離を促進し、抗原結合分子とFcRnの結合を促進する方法を挙げることができる。抗原が可溶型抗原の場合、抗原の結合の有無に関わらず抗原結合分子はFcRnに結合することができるが、抗原結合分子のエンドソーム内でのpH(酸性pH)における抗原結合能を血漿中でのpH(中性pH)における抗原結合能よりも弱くすることにより、エンドソーム内で抗原の抗原結合分子からの解離を促進することができれば、"抗原に結合していない"抗原結合分子とFcRnの結合を促進する方法を挙げることができる。 Furthermore, the present invention promotes the binding of FcRn to an antigen-binding molecule that is not bound to an antigen in cells by making the antigen-binding ability of the antigen-binding molecule at acidic pH weaker than that at neutral pH. Regarding the method. Normally, FcRn binds to an antigen-binding molecule in the endosome, but when the antigen-binding molecule is bound to a membrane-type antigen, it is considered that it cannot bind to FcRn. Therefore, as a preferred embodiment of the present invention, an antigen is used. In the case of a membrane-type antigen, the antigen-binding ability of the antigen-binding molecule at pH (acidic pH) in the endosome is weaker than the antigen-binding ability at pH (neutral pH) in plasma. Examples thereof include a method of promoting the dissociation of the antigen-binding molecule from the antigen and promoting the binding of the antigen-binding molecule to FcRn. When the antigen is a soluble antigen, the antigen-binding molecule can bind to FcRn regardless of the presence or absence of antigen binding, but the antigen-binding ability of the antigen-binding molecule at pH (acidic pH) in the endosome is measured in plasma. If the dissociation of the antigen from the antigen-binding molecule in the endosome can be promoted by making it weaker than the antigen-binding ability at pH (neutral pH), then the "non-antigen-binding" antigen-binding molecule and FcRn Can be mentioned as a method of promoting the binding of.
抗原が膜型、可溶型どちらの場合であっても、抗原に結合していない抗原結合分子がFcRnにより血漿中に戻ることが出来れば、再び抗原に結合することが可能であるため、これを繰り返すことで抗原結合分子は抗原に複数回結合することが可能である。本発明において、「細胞内での抗原結合分子とFcRnの結合を促進する」とは、全ての抗原結合分子がFcRnと結合する必要はなく、細胞内でFcRnと結合する抗原に結合していない抗原結合分子の割合が、抗原結合分子のエンドソーム内でのpHにおける抗原結合能を血漿中でのpHにおける抗原結合能を低くする前と比較して高くなっていればよい。本発明の細胞内での抗原結合分子とFcRnとの結合を促進する方法において好ましい抗原結合分子の例としては、膜タンパク質などの膜型抗原(膜抗原)に結合する抗原結合分子を挙げることができる。又、他の好ましい抗原結合分子としては、可溶型タンパク質などの可溶型抗原に結合する抗原結合分子を挙げることができる。 Regardless of whether the antigen is a membrane type or a soluble type, if the antigen-binding molecule that is not bound to the antigen can be returned to the plasma by FcRn, it can bind to the antigen again. The antigen-binding molecule can bind to the antigen multiple times by repeating. In the present invention, "promoting the binding of FcRn to an antigen-binding molecule in a cell" means that not all antigen-binding molecules need to bind to FcRn and do not bind to an antigen that binds to FcRn in a cell. The proportion of the antigen-binding molecule may be higher than before the antigen-binding ability of the antigen-binding molecule at pH in the endosome was lowered compared to before the antigen-binding ability at pH in plasma was lowered. An example of a preferred antigen-binding molecule in the method for promoting the binding of an antigen-binding molecule to FcRn in a cell of the present invention is an antigen-binding molecule that binds to a membrane-type antigen (membrane antigen) such as a membrane protein. it can. Further, as another preferable antigen-binding molecule, an antigen-binding molecule that binds to a soluble antigen such as a soluble protein can be mentioned.
又、細胞内での抗原結合分子とFcRnの結合を促進する方法は、抗原結合分子の細胞内(例えばエンドソーム内)でのFcRnとの結合活性を増強する方法ともいえる。 Further, the method of promoting the binding of the antigen-binding molecule to FcRn in the cell can be said to be a method of enhancing the binding activity of the antigen-binding molecule to FcRn in the cell (for example, endosome).
さらに本発明は、抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法に関する。本発明において、「抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる」とは、抗原と結合した状態で細胞内に取り込まれた抗原結合分子全てが抗原と結合していない状態で細胞外に放出される必要はなく、細胞外に放出される抗原結合分子の割合が抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能より低くする前と比較して高くなっていればよい。好ましくは、細胞外に放出された抗原結合分子は抗原結合能を維持している。又、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を抗原と結合していない状態で細胞外に放出させる方法は、抗原と結合して細胞内に取り込まれた場合に抗原と結合していない状態で細胞外に放出されやすくなる性質を抗原結合分子に付与する方法ともいえる。 Furthermore, the present invention binds an antigen-binding molecule incorporated into a cell in a state of being bound to an antigen to an antigen by making the antigen-binding ability of the antigen-binding molecule at an acidic pH weaker than that at a neutral pH. It relates to a method of releasing it to the outside of a cell in a state where it is not. In the present invention, "releasing an antigen-binding molecule that has been taken up into a cell in a state of being bound to an antigen to the outside of the cell in a state of not being bound to an antigen" means that the molecule is taken into the cell in a state of being bound to an antigen. It is not necessary for all of the antigen-binding molecules to be released extracellularly without being bound to the antigen, and the proportion of the antigen-binding molecules released extracellularly determines the antigen-binding ability of the antigen-binding molecule at the acidic pH. It suffices if it is higher than before it is lower than the antigen-binding ability in. Preferably, the antigen-binding molecule released extracellularly maintains the antigen-binding ability. In addition, the method of releasing an antigen-binding molecule that has been incorporated into a cell while bound to an antigen to the outside of the cell without binding to an antigen is a method in which the molecule binds to the antigen when it is bound to the antigen and incorporated into the cell. It can also be said to be a method of imparting the property of being easily released to the outside of the cell to the antigen-binding molecule in the untreated state.
さらに、本発明は抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることにより、抗原結合分子の血漿中抗原消失能を増加させる方法に関する。本発明において、「血漿中抗原消失能」とは、抗原結合分子が生体内に投与されたあるいは生体が分泌した際に、血漿中に存在する抗原を血漿中から消失させる能力のことをいう。従って、本発明において、「抗原結合分子の血漿中抗原消失能が増加する」とは、抗原結合分子を生体内に投与した際に血漿中から抗原が消失する速さが、抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能より低くする前と比較して速くなっていればよい。抗原結合分子の血漿中抗原消失能が増加したか否かは、例えば、可溶型抗原と抗原結合分子を生体内に投与し、投与後の可溶型抗原の血漿中濃度を測定することにより判断することが可能である。抗原結合分子の酸性pHにおける抗原結合能を中性pHにおける抗原結合能より低くすることにより、可溶型抗原および抗原結合分子投与後の血漿中の可溶型抗原の濃度が低下している場合には、抗原結合分子の血漿中抗原消失能が増加したと判断することができる。 Furthermore, the present invention relates to a method for increasing the plasma antigen elimination ability of an antigen-binding molecule by weakening the antigen-binding ability of the antigen-binding molecule at acidic pH to be weaker than the antigen-binding ability at neutral pH. In the present invention, the "plasma antigen-eliminating ability" refers to the ability to eliminate an antigen present in plasma from plasma when an antigen-binding molecule is administered into a living body or secreted by the living body. Therefore, in the present invention, "the ability of the antigen-binding molecule to eliminate the antigen in plasma increases" means that the rate at which the antigen disappears from the plasma when the antigen-binding molecule is administered in vivo is the acidity of the antigen-binding molecule. It suffices if the antigen-binding ability at pH is faster than before the antigen-binding ability at neutral pH is lowered. Whether or not the plasma antigen elimination ability of the antigen-binding molecule has increased can be determined by, for example, administering the soluble antigen and the antigen-binding molecule in vivo and measuring the plasma concentration of the soluble antigen after administration. It is possible to judge. When the concentration of the soluble antigen and the soluble antigen in the plasma after administration of the antigen-binding molecule is reduced by making the antigen-binding ability of the antigen-binding molecule lower than the antigen-binding ability at the neutral pH. It can be determined that the ability of the antigen-binding molecule to eliminate the antigen in plasma has increased.
さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、抗原結合分子の薬物動態を向上する方法に関する。 Furthermore, the present invention relates to a method for improving the pharmacokinetics of an antigen-binding molecule by substituting at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid.
又、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、抗原結合分子の抗原への結合回数を増やす方法を提供する。 The present invention also provides a method for increasing the number of times an antigen-binding molecule binds to an antigen by substituting at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid. ..
さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、抗原結合分子が結合可能な抗原の数を増やす方法に関する。 Furthermore, the present invention relates to a method of increasing the number of antigens to which an antigen-binding molecule can bind by substituting at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid.
さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法を提供する。 Furthermore, in the present invention, by substituting at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid, an antigen bound to the antigen-binding molecule extracellularly is antigenized intracellularly. A method for dissociating from a binding molecule is provided.
さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法を提供する。 Furthermore, the present invention is an antigen-binding molecule that is incorporated into a cell in a state of being bound to an antigen by replacing at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid. Provided a method for releasing the amino acid extracellularly without binding to the antigen.
さらに、本発明は抗原結合分子の少なくとも1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換する、又はヒスチジン又は非天然アミノ酸を挿入することにより、抗原結合分子の血漿中抗原消失能を増加させる方法を提供する。 Furthermore, the present invention provides a method for increasing the ability of an antigen-binding molecule to eliminate antigen in plasma by substituting at least one amino acid of the antigen-binding molecule with histidine or an unnatural amino acid, or by inserting a histidine or an unnatural amino acid. To do.
ヒスチジン又は非天然アミノ酸変異(置換、挿入等)が導入される位置は特に限定されず、如何なる部位がヒスチジン又は非天然アミノ酸に置換されてもよく、又は如何なる部位にヒスチジン又は非天然アミノ酸が挿入されてもよい。ヒスチジン又は非天然アミノ酸に置換又はヒスチジン又は非天然アミノ酸が挿入される部位の好ましい例として、抗原結合分子の抗原結合能に影響を与える領域を挙げることができる。例えば、抗原結合分子が抗体の場合には、抗体の可変領域やCDRなどを挙げることができる。ヒスチジン又は非天然アミノ酸変異が導入される数は特に限定されず、1箇所のみをヒスチジン又は非天然アミノ酸で置換してもよく、又は1箇所のみにヒスチジン又は非天然アミノ酸を挿入してもよい。あるいは2箇所以上の複数箇所をヒスチジン又は非天然アミノ酸で置換してもよく、又は複数箇所にヒスチジン又は非天然アミノ酸を挿入してもよい。又、ヒスチジン又は非天然アミノ酸への置換又は挿入以外に他のアミノ酸の欠失、付加、挿入および/または置換などを同時に行ってもよい。 The position where the histidine or unnatural amino acid mutation (substitution, insertion, etc.) is introduced is not particularly limited, and any site may be replaced with histidine or unnatural amino acid, or histidine or unnatural amino acid is inserted at any site. You may. A preferred example of a site where a histidine or an unnatural amino acid is substituted or a histidine or an unnatural amino acid is inserted can be a region that affects the antigen-binding ability of an antigen-binding molecule. For example, when the antigen-binding molecule is an antibody, the variable region of the antibody, CDR, and the like can be mentioned. The number of histidine or unnatural amino acid mutations introduced is not particularly limited, and only one site may be replaced with histidine or unnatural amino acid, or only one site may be inserted with histidine or unnatural amino acid. Alternatively, two or more sites may be replaced with histidine or an unnatural amino acid, or histidine or an unnatural amino acid may be inserted at the plurality of sites. In addition to substitution or insertion with histidine or unnatural amino acid, deletion, addition, insertion and / or substitution of other amino acids may be performed at the same time.
本発明においてヒスチジン又は非天然アミノ酸に置換される箇所の例として、抗原結合分子が抗体の場合には、抗体のCDR配列やCDRの構造を決定する配列が改変箇所として考えられ、例えば以下の箇所を挙げることができる。なお、アミノ酸位置はKabatナンバリング(Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest.NIH)で示している。 As an example of the site where the antigen-binding molecule is replaced with histidine or an unnatural amino acid in the present invention, when the antigen-binding molecule is an antibody, the CDR sequence of the antibody or the sequence that determines the CDR structure can be considered as the modification site. Can be mentioned. The amino acid positions are indicated by Kabat numbering (Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest. NIH).
重鎖:H27、H31、H32、H33、H35、H50、H58、H59、H61、H62、H63、H64、H65、H99、H100b、H102
軽鎖:L24、L27、L28、L32、L53、L54、L56、L90、L92、L94
Heavy chain: H27, H31, H32, H33, H35, H50, H58, H59, H61, H62, H63, H64, H65, H99, H100b, H102
Light chain: L24, L27, L28, L32, L53, L54, L56, L90, L92, L94
これらの改変箇所のうち、H32、H61、L53、L90、L94は普遍性の高い改変箇所と考えられる。 Of these modified parts, H32, H61, L53, L90, and L94 are considered to be highly universal modified parts.
又、特に限定されないが、抗原がIL-6受容体(例えば、ヒトIL-6受容体)の場合の好ましい改変箇所として以下の箇所を挙げることができる。 Further, although not particularly limited, the following sites can be mentioned as preferable modification sites when the antigen is an IL-6 receptor (for example, human IL-6 receptor).
重鎖:H27、H31、H32、H35、H50、H58、H61、H62、H63、H64、H65、H100b、H102
軽鎖:L24、L27、L28、L32、L53、L56、L90、L92、L94
Heavy chain: H27, H31, H32, H35, H50, H58, H61, H62, H63, H64, H65, H100b, H102
Light chain: L24, L27, L28, L32, L53, L56, L90, L92, L94
複数の箇所を組み合わせてヒスチジン又は非天然アミノ酸に置換する場合の好ましい組み合わせの具体例としては、例えば、H27、H31、H35の組み合わせ、H27、H31、H32、H35、H58、H62、H102の組み合わせ、L32、L53の組み合わせ、L28、L32、L53の組み合わせ等を挙げることができる。さらに、重鎖と軽鎖の置換箇所の好ましい組み合わせの例としては、H27、H31、L32、L53の組み合わせを挙げることができる。 Specific examples of preferable combinations when a plurality of sites are combined and replaced with histidine or an unnatural amino acid include, for example, a combination of H27, H31 and H35, a combination of H27, H31, H32, H35, H58, H62 and H102. The combination of L32 and L53, the combination of L28, L32 and L53, etc. can be mentioned. Furthermore, examples of preferred combinations of heavy chain and light chain substitution sites include combinations of H27, H31, L32, and L53.
又、特に限定されないが、抗原がIL-6(例えば、ヒトIL-6)の場合の好ましい改変箇所として以下の箇所を挙げることができる。 Further, although not particularly limited, the following sites can be mentioned as preferable modification sites when the antigen is IL-6 (for example, human IL-6).
重鎖:H32、H59、H61、H99
軽鎖:L53、L54、L90、L94
Heavy chain: H32, H59, H61, H99
Light chain: L53, L54, L90, L94
又、特に限定されないが、抗原がIL-31受容体(例えば、ヒトIL-31受容体)の場合の好ましい改変箇所としてH33を挙げることができる。 Further, although not particularly limited, H33 can be mentioned as a preferable modification site when the antigen is an IL-31 receptor (for example, a human IL-31 receptor).
これらの箇所は、1つの箇所のみヒスチジン又は非天然アミノ酸で置換してもよいし、複数の箇所をヒスチジン又は非天然アミノ酸で置換してもよい。 Only one of these sites may be replaced with histidine or an unnatural amino acid, or a plurality of sites may be replaced with histidine or an unnatural amino acid.
本発明の方法は、標的抗原の種類によらない任意の抗原結合分子に適応可能である。 The method of the present invention is applicable to any antigen-binding molecule regardless of the type of target antigen.
本発明において抗原結合分子は、対象とする抗原への特異的な結合活性を有する物質であれば特に限定されないが、抗原結合分子の好ましい例として、抗体の抗原結合領域を有している物質を挙げることができる。抗体の抗原結合領域の例としては、CDRや可変領域を挙げることができる。抗体の抗原結合領域がCDRである場合、全長抗体に含まれる6つのCDR全てを含んでいてもよいし、1つ若しくは2つ以上のCDRを含んでいてもよい。抗体の結合領域としてCDRを含む場合、含まれるCDRはアミノ酸の欠失、置換、付加及び/又は挿入などが行われていてもよく、又、CDRの一部分であってもよい。 In the present invention, the antigen-binding molecule is not particularly limited as long as it is a substance having a specific binding activity to the target antigen, but a preferable example of the antigen-binding molecule is a substance having an antigen-binding region of an antibody. Can be mentioned. Examples of the antigen-binding region of the antibody include CDR and variable region. When the antigen-binding region of the antibody is a CDR, it may contain all six CDRs contained in the full-length antibody, or it may contain one or more CDRs. When a CDR is included as the binding region of the antibody, the included CDR may be deleted, substituted, added and / or inserted with an amino acid, or may be a part of the CDR.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、抗原結合分子の薬物動態を向上する方法に関する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention modifies the antibody constant region contained in the antigen-binding molecule (substitution, deletion, addition and / or insertion of amino acids, etc.) to obtain the antigen-binding molecule. On how to improve the pharmacokinetics of.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、抗原結合分子の抗原への結合回数を増やす方法を提供する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention modifies the antibody constant region contained in the antigen-binding molecule (substitution, deletion, addition and / or insertion of amino acids, etc.) to obtain the antigen-binding molecule. Provide a method for increasing the number of times of binding to an antigen.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、抗原結合分子が結合可能な抗原の数を増やす方法に関する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention modifies the antibody constant region contained in the antigen-binding molecule (substitution, deletion, addition and / or insertion of amino acids, etc.) to obtain the antigen-binding molecule. On how to increase the number of antigens that can bind.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させる方法に関する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention presents the present invention extracellularly by modifying the antibody constant region contained in the antigen-binding molecule (such as substitution, deletion, addition and / or insertion of amino acids). The present invention relates to a method for dissociating an antigen bound to an antigen-binding molecule from the antigen-binding molecule in the cell.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させる方法に関する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention binds to the antigen by modifying the antibody constant region contained in the antigen-binding molecule (substitution, deletion, addition and / or insertion of amino acids, etc.). The present invention relates to a method for releasing an antigen-binding molecule that has been taken up into a cell in the state of being bound to the outside of the cell without being bound to an antigen.
さらに、抗原結合分子に抗体定常領域が含まれる場合、本発明は抗原結合分子に含まれる抗体定常領域を改変(アミノ酸の置換、欠失、付加および/又は挿入など)することにより、抗原結合分子の血漿中抗原消失能を増加させる方法に関する。 Furthermore, when the antigen-binding molecule contains an antibody constant region, the present invention modifies the antibody constant region contained in the antigen-binding molecule (substitution, deletion, addition and / or insertion of amino acids, etc.) to obtain the antigen-binding molecule. The present invention relates to a method for increasing the ability to eliminate antigens in plasma.
本発明の抗原結合物質の好ましい態様として、FcRn結合領域を含む抗原結合物質を挙げることができる。FcRn結合領域を含む抗原結合物質は、FcRnのサルベージ経路により細胞内に取り込まれた後に再び血漿中に戻ることが可能である。FcRn結合領域は、直接FcRnと結合する領域であることが好ましい。FcRn結合領域の好ましい例として、抗体のFc領域を挙げることができる。しかしながら、アルブミンやIgGなどのFcRnとの結合能を有するポリペプチドに結合可能な領域は、アルブミンやIgGなどを介して間接的にFcRnと結合することが可能であるので、本発明におけるFcRn結合領域はそのようなFcRnとの結合能を有するポリペプチドに結合する領域であってもよい。 As a preferred embodiment of the antigen-binding substance of the present invention, an antigen-binding substance containing an FcRn-binding region can be mentioned. The antigen-binding substance containing the FcRn-binding region can be taken up into cells by the salvage pathway of FcRn and then returned to plasma again. The FcRn binding region is preferably a region that directly binds to FcRn. A preferred example of the FcRn binding region is the Fc region of an antibody. However, a region capable of binding to a polypeptide having FcRn-binding ability such as albumin or IgG can indirectly bind to FcRn via albumin or IgG, and thus the FcRn-binding region in the present invention. May be a region that binds to a polypeptide capable of binding to such FcRn.
本発明の方法が対象とする抗体等の抗原結合分子が認識する抗原は特に限定されず、如何なる抗原を認識する抗体が対象となってもよい。本発明の方法により薬物動態を向上させる抗体の例としては、例えば、受容体蛋白質(膜結合型受容体、可溶型受容体)や細胞表面マーカーなどの膜抗原を認識する抗体、サイトカインなどの可溶型抗原を認識する抗体などを挙げることができる。本発明において、膜抗原の好ましい例として膜タンパク質を挙げることができる。又、本発明において可溶型抗原の例として可溶型タンパク質を挙げることができる。本発明の方法により薬物動態を向上させる抗体が認識する抗原の具体的な例としては、例えばIL-1、IL-2、IL-3、IL-4、IL-5、IL-6、IL-7、IL-8、IL-9、IL-10、IL-11、IL-12、IL-15、IL-31、IL-23、IL-2受容体、IL-6受容体、OSM受容体、gp130、IL-5受容体、CD40、CD4、Fas、オステオポンチン、CRTH2、CD26、PDGF-D、CD20、単球走化活性因子、CD23、TNF-α、HMGB-1、α4インテグリン、ICAM-1、CCR2、CD11a、CD3、IFNγ、BLyS、HLA-DR、TGF-β、CD52、IL-31受容体などを挙げることができる。特に好ましい抗原として、IL-6受容体を挙げることができる。 The antigen recognized by the antigen-binding molecule such as the antibody targeted by the method of the present invention is not particularly limited, and an antibody that recognizes any antigen may be the target. Examples of antibodies that improve pharmacokinetics by the method of the present invention include antibodies that recognize membrane antigens such as receptor proteins (membrane-bound receptors, soluble receptors) and cell surface markers, and cytokines. Examples thereof include antibodies that recognize soluble antigens. In the present invention, a membrane protein can be mentioned as a preferable example of the membrane antigen. Further, in the present invention, a soluble protein can be mentioned as an example of the soluble antigen. Specific examples of the antigen recognized by the antibody that improves pharmacokinetics by the method of the present invention include, for example, IL-1, IL-2, IL-3, IL-4, IL-5, IL-6, IL-. 7, IL-8, IL-9, IL-10, IL-11, IL-12, IL-15, IL-31, IL-23, IL-2 receptor, IL-6 receptor, OSM receptor, gp130, IL-5 receptor, CD40, CD4, Fas, osteopontin, CRTH2, CD26, PDGF-D, CD20, monocytic activator, CD23, TNF-α, HMGB-1, α4 integrin, ICAM-1, Examples thereof include CCR2, CD11a, CD3, IFNγ, BLyS, HLA-DR, TGF-β, CD52, IL-31 receptor and the like. A particularly preferred antigen is the IL-6 receptor.
又、本発明の方法が対象とする抗原結合分子としてはアンタゴニスト活性を有する抗原結合分子(アンタゴニスト抗原結合分子)、アゴニスト活性を有する抗原結合分子(アゴニスト抗原結合分子)などを挙げることができるが、好ましい態様として、アンタゴニスト抗原結合分子、特に受容体などの膜抗原やサイトカインなどの可溶型抗原を認識するアンタゴニスト抗原結合分子を挙げることができる。例えば、受容体を認識するアンタゴニスト抗原結合分子は、受容体に結合し、受容体とそのリガンドとの結合を阻害し、受容体を介したシグナル伝達を阻害する抗原結合分子である。 Further, examples of the antigen-binding molecule targeted by the method of the present invention include an antigen-binding molecule having an antagonist activity (antogen antigen-binding molecule) and an antigen-binding molecule having an agonist activity (agonist antigen-binding molecule). As a preferred embodiment, an antagonist antigen-binding molecule, particularly an antagonist antigen-binding molecule that recognizes a membrane antigen such as a receptor or a soluble antigen such as a cytokine can be mentioned. For example, an antagonist antigen-binding molecule that recognizes a receptor is an antigen-binding molecule that binds to a receptor, inhibits the binding of the receptor to its ligand, and inhibits signal transduction via the receptor.
本発明において対象となる抗原結合分子は特に限定されず、如何なる抗原結合分子でもよい。本発明で用いられる抗原結合分子は好ましくは、抗原結合活性(抗原結合領域)とFcRn結合領域を有する。本発明においては、特にヒトFcRnとの結合領域を含む抗原結合分子であることが好ましい。抗原結合活性とFcRn結合領域を有する抗原結合分子の例として、抗体を挙げることができる。本発明の抗体の好ましい例として、IgG抗体を挙げることができる。抗体としてIgG抗体を用いる場合、その種類は限定されず、IgG1、IgG2、IgG3、IgG4などのアイソタイプ(サブクラス)のIgGを用いることが可能である。また、これらのアイソタイプのIgGの定常領域に対して、M73のように定常領域部分にアミノ酸変異を導入しても良い。導入するアミノ酸変異は、例えば、Fcγレセプターへの結合を増大あるいは低減させたもの(Proc Natl Acad Sci U S A. 2006 Mar 14;103(11):4005-10.)、FcRnへの結合を増大あるいは低減させたもの(J Biol Chem. 2001 Mar 2;276(9):6591-604)等を挙げることができるが、これらに限定されるものではない。また、IgG2などの適切な定常領域を選択することによって、pH依存的な結合を変化させることも可能である。
The antigen-binding molecule of interest in the present invention is not particularly limited, and any antigen-binding molecule may be used. The antigen-binding molecule used in the present invention preferably has an antigen-binding activity (antigen-binding region) and an FcRn-binding region. In the present invention, an antigen-binding molecule containing a binding region with human FcRn is particularly preferable. An antibody can be mentioned as an example of an antigen-binding molecule having an antigen-binding activity and an FcRn-binding region. A preferred example of the antibody of the present invention is an IgG antibody. When an IgG antibody is used as the antibody, the type is not limited, and an isotype (subclass) of IgG such as IgG1, IgG2, IgG3, and IgG4 can be used. Further, for the constant region of these isotypes of IgG, an amino acid mutation may be introduced into the constant region portion such as M73. The amino acid mutations introduced are, for example, those with increased or decreased binding to the Fcγ receptor (Proc Natl Acad Sci US A. 2006
本発明が対象とする抗原結合分子が抗体の場合、抗体はマウス抗体、ヒト抗体、ラット抗体、ウサギ抗体、ヤギ抗体、ラクダ抗体など、どのような動物由来の抗体でもよい。さらに、例えば、キメラ抗体、中でもヒト化抗体などのアミノ酸配列を置換した改変抗体でもよい。また、二種特異性抗体、各種分子を結合させた抗体修飾物、抗体断片を含むポリペプチドなどであってもよい。 When the antigen-binding molecule targeted by the present invention is an antibody, the antibody may be any animal-derived antibody such as a mouse antibody, a human antibody, a rat antibody, a rabbit antibody, a goat antibody, and a camel antibody. Further, for example, a chimeric antibody, particularly a modified antibody in which the amino acid sequence of a humanized antibody or the like is substituted may be used. Further, it may be a bispecific antibody, an antibody modified product in which various molecules are bound, a polypeptide containing an antibody fragment, or the like.
「キメラ抗体」とは、異なる動物由来の配列を組合わせて作製される抗体である。キメラ抗体の具体的な例としては、例えば、マウス抗体の重鎖、軽鎖の可変(V)領域とヒト抗体の重鎖、軽鎖の定常(C)領域からなる抗体を挙げることができる。 A "chimeric antibody" is an antibody produced by combining sequences derived from different animals. Specific examples of the chimeric antibody include an antibody composed of a variable (V) region of a heavy chain and a light chain of a mouse antibody and a heavy chain and a constant (C) region of a light chain of a human antibody.
「ヒト化抗体」とは、再構成(reshaped)ヒト抗体とも称される、ヒト以外の哺乳動物由来の抗体、例えばマウス抗体の相補性決定領域(CDR;complementarity determining region)をヒト抗体のCDRへ移植したものである。CDRを同定するための方法は公知である(Kabat et al., Sequence of Proteins of Immunological Interest (1987), National Institute of Health, Bethesda, Md.; Chothia et al., Nature (1989) 342: 877)。また、その一般的な遺伝子組換え手法も公知である(欧州特許出願公開番号EP 125023号公報、WO 96/02576 号公報参照)。 A "humanized antibody" is an antibody derived from a non-human mammal, which is also called a reshaped human antibody, for example, a mouse antibody's complementarity determining region (CDR) is transferred to the human antibody's CDR. It is a transplant. Methods for identifying CDRs are known (Kabat et al., Sequence of Proteins of Immunological Interest (1987), National Institute of Health, Bethesda, Md .; Chothia et al., Nature (1989) 342: 877). .. The general gene recombination method is also known (see European Patent Application Publication No. EP 125023, WO 96/02576).
二重特異性抗体は、異なるエピトープを認識する可変領域を同一の抗体分子内に有する抗体をいう。二種特異性抗体は2つ以上の異なる抗原を認識する抗体であってもよいし、同一抗原上の異なる2つ以上のエピトープを認識する抗体であってもよい。 Bispecific antibody refers to an antibody that has a variable region that recognizes different epitopes in the same antibody molecule. The bispecific antibody may be an antibody that recognizes two or more different antigens, or an antibody that recognizes two or more different epitopes on the same antigen.
又、抗体断片を含むポリペプチドとしては、例えば、Fab断片、F(ab')2断片、scFv(Nat Biotechnol. 2005 Sep;23(9):1126-36.)domain antibody(dAb)(WO2004/058821, WO2003/002609)、scFv-Fc(WO2005037989)、dAb-Fc、Fc融合タンパク質等が挙げられる。これらの分子のうち、特にFc領域を含んでいる分子はFcRnへの結合活性を有することから、本発明で見出された方法を用いるのに適している。 Examples of the polypeptide containing the antibody fragment include Fab fragment, F (ab') 2 fragment, scFv (Nat Biotechnol. 2005 Sep; 23 (9): 1126-36.) Domain antibody (dAb) (WO2004 / 058821, WO2003 / 002609), scFv-Fc (WO2005037989), dAb-Fc, Fc fusion protein and the like. Among these molecules, a molecule containing an Fc region in particular has an FcRn-binding activity, and thus is suitable for using the method found in the present invention.
さらに、本発明が適用できる抗原結合分子は、抗体様分子であってもよい。抗体様分子とは、ターゲット分子に結合することで機能を発揮するような分子であり(Current Opinion in Biotechnology 2006, 17:653-658、Current Opinion in Biotechnology 2007, 18:1-10、Current Opinion in Structural Biology 1997, 7:463-469、Protein Science 2006, 15:14-27)、例えば、DARPins(WO2002/020565)、Affibody(WO1995/001937)、Avimer(WO2004/044011, WO2005/040229)、Adnectin(WO2002/032925)等が挙げられる。これら抗体様分子であっても、標的分子に対してpH依存的に結合することが出来れば、1分子で複数の標的分子に結合することが可能である。 Furthermore, the antigen-binding molecule to which the present invention can be applied may be an antibody-like molecule. An antibody-like molecule is a molecule that exerts its function by binding to a target molecule (Current Opinion in Biotechnology 2006, 17: 653-658, Current Opinion in Biotechnology 2007, 18: 1-10, Current Opinion in Structural Biology 1997, 7: 463-469, Protein Science 2006, 15: 14-27), for example, DARPins (WO2002 / 020565), Affibody (WO1995 / 001937), Avimer (WO2004 / 044011, WO2005 / 040229), Adnectin ( WO2002 / 032925) and the like. Even with these antibody-like molecules, if they can bind to the target molecule in a pH-dependent manner, one molecule can bind to a plurality of target molecules.
また抗原結合分子は、標的に結合するレセプタータンパク質およびレセプターFc融合タンパク質であっても良く、例えば、TNFR-Fc融合タンパク、IL1R-Fc融合タンパク、VEGFR-Fc融合タンパク、CTLA4-Fc融合タンパク等(Nat Med. 2003 Jan;9(1):47-52、BioDrugs. 2006;20(3):151-60.)が挙げられる。これらレセプタータンパク質およびレセプターFc融合タンパク質であっても標的分子に対してpH依存的に結合することが出来れば、1分子で複数の標的分子に結合することが可能である。 The antigen-binding molecule may be a receptor protein that binds to a target and a receptor Fc fusion protein, such as TNFR-Fc fusion protein, IL1R-Fc fusion protein, VEGFR-Fc fusion protein, CTLA4-Fc fusion protein, and the like ( Nat Med. 2003 Jan; 9 (1): 47-52, BioDrugs. 2006; 20 (3): 151-60.). Even these receptor proteins and receptor Fc fusion proteins can bind to a plurality of target molecules with one molecule if they can bind to the target molecule in a pH-dependent manner.
また抗原結合分子は、標的に結合するが中和効果を有する人工リガンドタンパク質および人工リガンド融合タンパク質であっても良く、例えば、変異IL-6(EMBO J. 1994 Dec 15;13(24):5863-70.)等が挙げられる。これら人工リガンドタンパク質および人工リガンド融合タンパク質であっても標的分子に対してpH依存的に結合することが出来れば、1分子で複数の標的分子に結合することが可能である。
The antigen-binding molecule may also be an artificial ligand protein and an artificial ligand fusion protein that bind to the target but have a neutralizing effect, for example, mutant IL-6 (EMBO J. 1994
さらに、本発明の抗体は糖鎖が改変されていてもよい。糖鎖が改変された抗体の例としては、例えば、グリコシル化が修飾された抗体(WO99/54342など)、糖鎖に付加するフコースが欠損した抗体(WO00/61739、WO02/31140、WO2006/067847、WO2006/067913など)、バイセクティングGlcNAcを有する糖鎖を有する抗体(WO02/79255など)などを挙げることができる。 Furthermore, the antibody of the present invention may have a modified sugar chain. Examples of sugar chain-modified antibodies include, for example, glycosylation-modified antibodies (WO99 / 54342, etc.) and fucose-deficient antibodies attached to sugar chains (WO00 / 61739, WO02 / 31140, WO2006 / 067847). , WO2006 / 067913, etc.), antibodies having sugar chains with bisecting GlcNAc (WO02 / 79255, etc.), and the like.
本発明の方法は特定の理論により限定されるものではないが、例えば、酸性pHにおける抗原結合能を中性pHにおける抗原結合能よりも弱くすることと薬物動態の向上、および、複数回の抗原への結合との関連は以下のように説明することが可能である。 The method of the present invention is not limited by a specific theory, but for example, making the antigen-binding ability at acidic pH weaker than the antigen-binding ability at neutral pH, improving pharmacokinetics, and multiple antigens. The association with the binding to to can be explained as follows.
例えば、抗体が膜抗原に結合する抗体の場合、生体内に投与した抗体は抗原に結合して、その後、抗体は抗原に結合したまま抗原と一緒にインターナライゼーションによって細胞内のエンドソームに取り込まれる。その後、抗体は抗原に結合したままライソソームへ移行し抗体は抗原と一緒にライソソームにより分解される。インターナライゼーションを介した血漿中からの消失は抗原依存的な消失と呼ばれており、多くの抗体分子で報告されている(Drug Discov Today. 2006 Jan;11(1-2):81-8)。1分子のIgG抗体が2価で抗原に結合した場合、1分子の抗体が2分子の抗原に結合した状態でインターナライズされ、そのままライソソームで分解される。従って、通常の抗体の場合、1分子のIgG抗体が3分子以上の抗原に結合することは出来ない。例えば、中和活性を有する1分子のIgG抗体の場合、3分子以上の抗原を中和することはできない。 For example, in the case of an antibody that binds to a membrane antigen, the antibody administered in vivo binds to the antigen, and then the antibody is taken up into intracellular endosomes by internalization together with the antigen while being bound to the antigen. After that, the antibody is transferred to the lysosome while being bound to the antigen, and the antibody is degraded by the lysosome together with the antigen. Plasma elimination via internalization is called antigen-dependent elimination and has been reported in many antibody molecules (Drug Discov Today. 2006 Jan; 11 (1-2): 81-8). .. When one molecule of IgG antibody binds to an antigen with divalent value, one molecule of antibody is internalized in a state of being bound to two molecules of antigen, and is directly degraded by lysosome. Therefore, in the case of a normal antibody, one molecule of IgG antibody cannot bind to three or more molecules of antigen. For example, in the case of one molecule of IgG antibody having neutralizing activity, three or more molecules of antigen cannot be neutralized.
IgG分子の血漿中滞留性が比較的長い(消失が遅い)のは、IgG分子のサルベージレセプターとして知られているFcRnが機能しているためである。ピノサイトーシスによってエンドソームに取り込まれたIgG分子は、エンドソーム内の酸性条件下においてエンドソーム内に発現しているFcRnに結合する。FcRnに結合できなかったIgG分子はライソソームへと進みそこで分解されるが、FcRnへ結合したIgG分子は細胞表面へ移行し血漿中の中性条件下においてFcRnから解離することで再び血漿中に戻る。 The relatively long plasma retention of IgG molecules (slow disappearance) is due to the functioning of FcRn, which is known as a salvage receptor for IgG molecules. IgG molecules incorporated into endosomes by pinocytosis bind to FcRn expressed in endosomes under acidic conditions within endosomes. IgG molecules that could not bind to FcRn proceed to the lysosome and are degraded there, but IgG molecules that bind to FcRn migrate to the cell surface and dissociate from FcRn under neutral conditions in plasma, returning to plasma again. ..
又、抗体が可溶型抗原に結合する抗体の場合、生体内に投与した抗体は抗原に結合し、その後、抗体は抗原に結合したまま細胞内に取り込まれる。細胞内に取り込まれた抗体の多くはFcRnにより細胞外に放出されるが、抗原に結合したまま細胞外に放出される為、再度、抗原に結合することはできない。従って、膜抗原に結合する抗体と同様、通常の抗体の場合、1分子のIgG抗体が3分子以上の抗原に結合することはできない。 When the antibody binds to a soluble antigen, the antibody administered in vivo binds to the antigen, and then the antibody is taken up into the cell while being bound to the antigen. Most of the antibodies taken up into the cell are released extracellularly by FcRn, but since they are released extracellularly while bound to the antigen, they cannot bind to the antigen again. Therefore, like an antibody that binds to a membrane antigen, in the case of a normal antibody, one molecule of IgG antibody cannot bind to three or more molecules of antigen.
本発明者らは、インターナライゼーションによって膜抗原などの抗原に結合した抗体が細胞内のエンドソームに取り込まれた際に、抗原に結合したままの抗体はライソソームに移行して分解されるのに対して、エンドソーム内において抗原が解離したIgG抗体はエンドソーム内に発現しているFcRnに結合することが出来ると考えた。つまり、血漿中では抗原に強く結合し、エンドソーム内では抗原に弱く結合する抗体は、血漿中で抗原に結合して抗原との複合体を形成したままインターナライゼーションによって細胞内のエンドソーム内に取り込まれ、エンドソーム内で抗原と解離した後に、FcRnに結合して細胞表面に移行し、抗原に結合していない状態で再び血漿中に戻り、複数個の膜型抗原を中和できることを見出した。さらに、血漿中では抗原に強く結合し、エンドソーム内では抗原に弱く結合する性質を有する抗体は、可溶型抗原などの抗原に結合した場合でも、エンドソーム内で抗原と解離することから、抗原に結合していない状態で再び血漿中に放出され、複数個の可溶型抗原を中和できることを見出した。 In contrast to the above, when an antibody bound to an antigen such as a membrane antigen is taken up by intracellular endosomes by internalization, the antibody remaining bound to the antigen is transferred to the lysosome and degraded. It was considered that the IgG antibody whose antigen was dissociated in the endosome could bind to FcRn expressed in the endosome. That is, an antibody that strongly binds to an antigen in plasma and weakly binds to an antigen in endosomes is taken up into intracellular endosomes by internalization while binding to the antigen in plasma and forming a complex with the antigen. It was found that after dissociating with an antigen in endosomes, it binds to FcRn and migrates to the cell surface, returns to plasma again in a state where it is not bound to an antigen, and can neutralize a plurality of membrane-type antigens. Furthermore, an antibody that binds strongly to an antigen in plasma and weakly binds to an antigen in endosomes dissociates from the antigen in endosomes even when bound to an antigen such as a soluble antigen. It has been found that it is released into plasma again in an unbound state and can neutralize a plurality of soluble antigens.
特に、本発明者らは血漿中のpHとエンドソーム内のpHが異なることに着目し、血漿中のpH条件では抗原に強く結合し、エンドソーム内のpH条件では抗原に弱く結合する抗体は1抗体分子が複数の抗原に結合することができ、血漿中滞留性が優れていることを見出した。 In particular, the present inventors have focused on the difference between the pH in plasma and the pH in endosomes, and one antibody that binds strongly to an antigen under pH conditions in plasma and weakly binds to an antigen under pH conditions in endosomes. It was found that the molecule can bind to a plurality of antigens and has excellent retention in plasma.
エンドソームは膜小胞の一つであり、真核細胞から細胞質内にネットワークを形成して細胞膜からリソソームに至る過程で高分子の代謝をつかさどる。エンドソーム内のpHは一般的にpH5.5〜pH6.0の酸性であることが報告されており(Nat Rev Mol Cell Biol. 2004 Feb;5(2):121-32.)、又、血漿中のpHはほぼ中性(通常、pH7.4)であることが知られている。 Endosomes are one of the membrane vesicles and control the metabolism of macromolecules in the process from eukaryotic cells to the cytoplasm and from the cell membrane to lysosomes. It has been reported that the pH in endosomes is generally acidic from pH 5.5 to pH 6.0 (Nat Rev Mol Cell Biol. 2004 Feb; 5 (2): 121-32.), And also in plasma. It is known that the pH of is almost neutral (usually pH 7.4).
従って、酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性よりも弱い抗原結合分子は、中性pHの血漿中において抗原に結合し、細胞内に取り込まれた後に、酸性pHのエンドソーム内で抗原と解離する。抗原と解離した抗原結合分子はFcRnに結合して細胞表面に移行し、抗原と結合していない状態で再び血漿中に戻り、結果として抗原と複数回結合することができ、薬物動態が向上する。 Therefore, an antigen-binding molecule whose antigen-binding activity at acidic pH is weaker than that at neutral pH binds to the antigen in plasma at neutral pH, is taken up into cells, and then in endosomes at acidic pH. Dissociates from the antigen. The antigen-binding molecule dissociated from the antigen binds to FcRn and translocates to the cell surface, returns to plasma again in a state where it is not bound to the antigen, and as a result, can bind to the antigen multiple times, improving pharmacokinetics. ..
<抗原結合分子物質>
さらに、本発明はpH4.0〜pH6.5での抗原結合活性がpH6.7〜pH10.0での抗原結合活性よりも低い抗原結合分子、好ましくはpH5.0〜pH6.0での抗原結合活性がpH7.0〜8.0での抗原結合活性よりも低い抗原結合分子を提供する。pH4.0〜pH6.5での抗原結合活性がpH6.7〜10.0での抗原結合活性よりも低い抗原結合分子の具体的な例としては、pH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子を挙げることができる。又、pH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子は、pH7.4での抗原結合活性がpH5.8での抗原結合活性よりも高い抗原結合分子ということもできる。
<Antigen-binding molecular substance>
Furthermore, the present invention relates to antigen-binding molecules whose antigen-binding activity at pH 4.0 to pH 6.5 is lower than that at pH 6.7 to pH 10.0, preferably antigen-binding at pH 5.0 to pH 6.0. It provides an antigen-binding molecule whose activity is lower than its antigen-binding activity at pH 7.0-8.0. As a specific example of an antigen-binding molecule whose antigen-binding activity at pH 4.0 to pH 6.5 is lower than that at pH 6.7 to 10.0, an antigen-binding activity at pH 5.8 is pH 7.4. Can be mentioned as an antigen-binding molecule having a lower antigen-binding activity than that of. In addition, an antigen-binding molecule whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4 is an antigen-binding molecule whose antigen-binding activity at pH 7.4 is higher than that at pH 5.8. You can also say that.
本発明のpH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子は、pH5.8での抗原結合活性がpH7.4での結合より低い限り、その結合活性の差は限定されず、僅かでもpH5.8における抗原結合活性が低ければよい。 The antigen-binding molecule of the present invention whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4 has its binding activity as long as its antigen-binding activity at pH 5.8 is lower than that at pH 7.4. The difference is not limited, and it is sufficient that the antigen-binding activity at pH 5.8 is low.
本発明のpH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい態様として、pH7.4における抗原結合活性がpH5.8における抗原結合活性の2倍以上である抗原結合分子を挙げることができ、さらに好ましい態様としてはpH7.4における抗原結合活性がpH5.8における抗原結合活性の10倍以上である抗原結合分子を挙げることができ、より好ましい態様としてはpH7.4における抗原結合活性がpH5.8における抗原結合活性の40倍以上である抗原結合分子を挙げることができる。 As a preferred embodiment of the antigen-binding molecule of the present invention whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4, the antigen-binding activity at pH 7.4 is at least twice the antigen-binding activity at pH 5.8. As a more preferable embodiment, an antigen-binding molecule having an antigen-binding activity at pH 7.4 that is 10 times or more the antigen-binding activity at pH 5.8 can be mentioned, and a more preferable embodiment can be mentioned. Can be mentioned as an antigen-binding molecule whose antigen-binding activity at pH 7.4 is 40 times or more the antigen-binding activity at pH 5.8.
具体的には、本発明のpH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい態様として、抗原に対するpH5.8でのKDとpH7.4でのKDの比であるKD(pH5.8)/KD(pH7.4)の値が2以上であり、さらに好ましくはKD(pH5.8)/KD(pH7.4)の値が10以上であり、さらに好ましくはKD(pH5.8)/KD(pH7.4)の値が40以上である。KD(pH5.8)/KD(pH7.4)の値の上限は特に限定されず、当業者の技術において作製可能な限り、400、1000、10000等、いかなる値でもよい。 Specifically, as a preferred embodiment of the antigen-binding molecule whose antigen-binding activity at pH 5.8 of the present invention is lower than that at pH 7.4, KD at pH 5.8 and pH 7.4 for the antigen The value of KD (pH 5.8) / KD (pH 7.4), which is the ratio of KD, is 2 or more, and more preferably the value of KD (pH 5.8) / KD (pH 7.4) is 10 or more. More preferably, the value of KD (pH 5.8) / KD (pH 7.4) is 40 or more. The upper limit of the value of KD (pH 5.8) / KD (pH 7.4) is not particularly limited, and may be any value such as 400, 1000, 10000, etc. as long as it can be produced by a person skilled in the art.
さらに本発明のpH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい他の態様として、抗原に対するpH5.8でのkdとpH7.4でのkdの比であるkd(pH5.8)/kd(pH7.4)の値が2以上であり、さらに好ましくはkd(pH5.8)/kd(pH7.4)の値が5以上であり、さらに好ましくはkd(pH5.8)/kd(pH7.4)の値が10以上であり、さらに好ましくはkd(pH5.8)/kd(pH7.4)の値が30以上である。Kd(pH5.8)/kd(pH7.4)の値の上限は特に限定されず、当業者の技術において作製可能な限り、50、100、200等、いかなる値でもよい。 Furthermore, as another preferred embodiment of the antigen-binding molecule of the present invention whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4, k d at pH 5.8 and k at pH 7.4 for the antigen. The value of k d (pH 5.8) / k d (pH 7.4), which is the ratio of d , is 2 or more, and more preferably the value of k d (pH 5.8) / k d (pH 7.4) is 5. above, still preferably at k d (pH5.8) / k value of d (pH 7.4) is 10 or more, more preferably k d (pH5.8) / k value of d (pH 7.4) Is 30 or more. The upper limit of the value of K d (pH 5.8) / k d (pH 7.4) is not particularly limited, and any value such as 50, 100, 200, etc. may be used as long as it can be produced by a person skilled in the art.
抗原の結合活性を測定する際のpH以外の条件は当業者が適宜選択することが可能であり、特に限定されないが、例えば、実施例に記載のようにMESバッファー、37℃の条件において測定することが可能である。又、抗原結合分子の抗原結合活性の測定は当業者に公知の方法により行うことが可能であり、例えば、実施例に記載のようにBiacore T100(GE Healthcare)などを用いて測定することが可能である。 Conditions other than pH when measuring the binding activity of the antigen can be appropriately selected by those skilled in the art and are not particularly limited, but for example, the measurement is performed under the conditions of MES buffer and 37 ° C. as described in Examples. It is possible. Further, the antigen-binding activity of the antigen-binding molecule can be measured by a method known to those skilled in the art, and for example, it can be measured using Biacore T100 (GE Healthcare) or the like as described in Examples. Is.
このような酸性pHにおいて抗原に弱く結合する抗原結合分子は、エンドソーム内の酸性条件下において抗原から容易に解離すると考えられ、細胞内にインターナライズされた後にFcRnと結合して細胞外に放出されやすいと考えられる。細胞内で分解されることなく、細胞外に放出された抗原結合分子は再度、抗原に結合することが可能である。従って、例えば抗原結合分子が中和抗原結合分子である場合には、エンドソーム内の酸性条件下において抗原から解離しやすい抗原結合分子は、複数回、抗原に結合し、抗原を中和することが可能である。結果として、pH4.0〜pH6.5での抗原結合活性がpH6.7〜pH10.0での抗原結合活性よりも低い抗原結合分子は血漿中滞留性において優れた抗原結合分子となる。 An antigen-binding molecule that binds weakly to an antigen at such an acidic pH is considered to be easily dissociated from the antigen under acidic conditions in endosomes, is internalized intracellularly, and then binds to FcRn and is released extracellularly. It is considered easy. The antigen-binding molecule released extracellularly without being degraded intracellularly can bind to the antigen again. Therefore, for example, when the antigen-binding molecule is a neutralizing antigen-binding molecule, the antigen-binding molecule that easily dissociates from the antigen under acidic conditions in the endosome may bind to the antigen multiple times to neutralize the antigen. It is possible. As a result, an antigen-binding molecule having an antigen-binding activity at pH 4.0 to pH 6.5 lower than that at pH 6.7 to pH 10.0 becomes an antigen-binding molecule having excellent plasma retention.
pH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい態様として、抗原結合分子中のアミノ酸の少なくとも1つがヒスチジン又は非天然アミノ酸に置換されている又は少なくとも1つのヒスチジン又は非天然アミノ酸が挿入されている抗原結合分子を挙げることができる。ヒスチジン又は非天然アミノ酸変異が導入される位置は特に限定されず、置換前と比較してpH5.8における抗原結合活性がpH7.4における抗原結合活性より弱くなる(KD(pH5.8)/KD(pH7.4)の値が大きくなる、又はkd(pH5.8)/kd(pH7.4)の値が大きくなる)限り、如何なる部位でもよい。例えば、抗原結合分子が抗体の場合には、抗体の可変領域やCDRなどを挙げることができる。ヒスチジン又は非天然アミノ酸に置換されるアミノ酸の数、又は挿入されるアミノ酸の数は当業者が適宜決定することができ、1つのアミノ酸をヒスチジン又は非天然アミノ酸で置換してもよいし、1つのアミノ酸を挿入してもよいし、2つ以上の複数のアミノ酸をヒスチジン又は非天然アミノ酸で置換してもよいし、2つ以上のアミノ酸を挿入してもよい。又、ヒスチジン又は非天然アミノ酸への置換又はヒスチジン又は非天然アミノ酸の挿入以外に、他のアミノ酸の欠失、付加、挿入および/または置換などを同時に行ってもよい。ヒスチジン又は非天然アミノ酸への置換又はヒスチジン又は非天然アミノ酸の挿入は、当業者の公知のアラニンscanningのアラニンをヒスチジンに置き換えたヒスチジンscanningなどの方法によりランダムに行ってもよく、ヒスチジン又は非天然アミノ酸変異がランダムに導入された抗原結合分子の中から、変異前と比較してKD(pH5.8)/KD(pH7.4)又はkd(pH5.8)/kd(pH7.4)の値が大きくなった抗原結合分子を選択してもよい。 A preferred embodiment of an antigen-binding molecule having a lower antigen-binding activity at pH 5.8 than that at pH 7.4 is that at least one of the amino acids in the antigen-binding molecule is replaced with histidine or an unnatural amino acid, or at least. An antigen-binding molecule in which one histidine or an unnatural amino acid is inserted can be mentioned. The position where the histidine or unnatural amino acid mutation is introduced is not particularly limited, and the antigen-binding activity at pH 5.8 is weaker than that at pH 7.4 (KD (pH 5.8) / KD). Any site may be used as long as the value of (pH 7.4) is increased or the value of k d (pH 5.8) / k d (pH 7.4) is increased). For example, when the antigen-binding molecule is an antibody, the variable region of the antibody, CDR, and the like can be mentioned. The number of amino acids to be replaced with histidine or unnatural amino acid, or the number of amino acids to be inserted can be appropriately determined by those skilled in the art, and one amino acid may be replaced with histidine or unnatural amino acid, or one amino acid may be substituted. Amino acids may be inserted, two or more amino acids may be replaced with histidine or unnatural amino acids, or two or more amino acids may be inserted. In addition to substitution with histidine or unnatural amino acid or insertion of histidine or unnatural amino acid, deletion, addition, insertion and / or substitution of other amino acids may be performed at the same time. Substitution with histidine or unnatural amino acid or insertion of histidine or unnatural amino acid may be performed randomly by a method such as histidine scanning in which alanine of alanine scanning known to those skilled in the art is replaced with histidine, or histidine or unnatural amino acid. Among the antigen-binding molecules into which the mutation was randomly introduced, KD (pH 5.8) / KD (pH 7.4) or k d (pH 5.8) / k d (pH 7.4) compared to before the mutation An antigen-binding molecule having a higher value may be selected.
このようにヒスチジン又は非天然アミノ酸への変異が行われ、かつpH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい例として、例えば、ヒスチジン又は非天然アミノ酸への変異後のpH7.4での抗原結合活性がヒスチジン又は非天然アミノ酸への変異前のpH7.4での抗原結合活性と同等である抗原結合分子を挙げることができる。本発明において、ヒスチジン又は非天然アミノ酸変異後の抗原結合分子が、ヒスチジン又は非天然アミノ酸変異前の抗原結合分子と同等の抗原結合活性を有するとは、ヒスチジン又は非天然アミノ酸変異前の抗原結合分子の抗原結合活性を100%とした場合に、ヒスチジン又は非天然アミノ酸変異後の抗原結合分子の抗原結合活性が少なくとも10%以上、好ましくは50%以上、さらに好ましくは80%以上、より好ましくは90%以上であることを言う。ヒスチジン又は非天然アミノ酸変異後のpH7.4での抗原結合活性がヒスチジン又は非天然アミノ酸変異前のpH7.4での抗原結合活性より高くなってもよい。ヒスチジン又は非天然アミノ酸への置換又は挿入により抗原結合分子の抗原結合活性が低くなった場合には、抗原結合分子中の1又は複数のアミノ酸の置換、欠失、付加及び/又は挿入などにより抗原結合活性をヒスチジン置換又は挿入前の抗原結合活性と同等にしてもよい。本発明においては、そのようなヒスチジン置換又は挿入後に1又は複数のアミノ酸の置換、欠失、付加及び/又は挿入を行うことにより結合活性が同等となった抗原結合分子も含まれる。 A preferred example of an antigen-binding molecule that is thus mutated to histidine or an unnatural amino acid and whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4 is, for example, histidine or unnatural. Examples thereof include antigen-binding molecules whose antigen-binding activity at pH 7.4 after mutation to an amino acid is equivalent to that at pH 7.4 before mutation to histidine or an unnatural amino acid. In the present invention, the antigen-binding molecule after histidine or unnatural amino acid mutation has the same antigen-binding activity as the antigen-binding molecule before histidine or unnatural amino acid mutation. When the antigen-binding activity of is 100%, the antigen-binding activity of the antigen-binding molecule after histidine or unnatural amino acid mutation is at least 10% or more, preferably 50% or more, more preferably 80% or more, more preferably 90. Say that it is greater than or equal to%. The antigen-binding activity at pH 7.4 after the histidine or unnatural amino acid mutation may be higher than the antigen-binding activity at pH 7.4 before the histidine or unnatural amino acid mutation. When the antigen-binding activity of an antigen-binding molecule is reduced by substitution or insertion with histidine or an unnatural amino acid, the antigen is antigen by substitution, deletion, addition and / or insertion of one or more amino acids in the antigen-binding molecule. The binding activity may be comparable to the antigen binding activity prior to histidine substitution or insertion. The present invention also includes antigen-binding molecules having equivalent binding activity by substituting, deleting, adding and / or inserting one or more amino acids after such histidine substitution or insertion.
さらに、抗原結合分子が抗体定常領域を含む物質である場合、pH5.8での抗原結合活性がpH7.4での抗原結合活性よりも低い抗原結合分子の好ましい他の態様として、抗原結合分子に含まれる抗体定常領域が改変された方法を挙げることができる。改変後の抗体定常領域の具体例としては、例えば実施例に記載の定常領域を挙げることができる。 Furthermore, when the antigen-binding molecule is a substance containing an antibody constant region, the antigen-binding molecule is designated as another preferred embodiment of the antigen-binding molecule whose antigen-binding activity at pH 5.8 is lower than that at pH 7.4. Examples thereof include a method in which the contained antibody constant region is modified. Specific examples of the modified antibody constant region include the constant region described in Examples.
上述の方法等により抗原結合物質のpH5.8における抗原結合活性をpH7.4における抗原結合活性より弱くする(KD(pH5.8)/KD(pH7.4)の値を大きくする)場合、特に限定されないが、KD(pH5.8)/KD(pH7.4)の値が基の抗体と比較して通常、2倍以上、好ましくは5倍以上、さらに好ましくは10倍以上となっていることが好ましい。 Especially when the antigen-binding activity of the antigen-binding substance at pH 5.8 is weaker than the antigen-binding activity at pH 7.4 (the value of KD (pH 5.8) / KD (pH 7.4) is increased) by the above method or the like. Although not limited, the value of KD (pH 5.8) / KD (pH 7.4) is usually 2 times or more, preferably 5 times or more, and more preferably 10 times or more that of the base antibody. Is preferable.
本発明の抗原結合分子はpH4.0〜pH6.5での抗原結合活性がpH6.7〜10.0での抗原結合活性よりも低い限り、他にどのような性質を有していてもよく、例えばアゴニスト抗原結合分子やアンタゴニスト抗原結合分子などであってもよい。本発明の好ましい抗原結合分子の例としてアンタゴニスト抗原結合分子を挙げることができる。アンタゴニスト抗原結合分子は通常、リガンド(アゴニスト)と受容体の結合を阻害し、受容体を介した細胞内へのシグナル伝達を阻害する抗原結合分子である。 The antigen-binding molecule of the present invention may have any other properties as long as the antigen-binding activity at pH 4.0 to pH 6.5 is lower than the antigen-binding activity at pH 6.7 to 10.0, for example. It may be an agonist antigen-binding molecule, an antagonist antigen-binding molecule, or the like. An antagonist antigen-binding molecule can be mentioned as an example of a preferable antigen-binding molecule of the present invention. Antagonist antigen-binding molecule is usually an antigen-binding molecule that inhibits the binding of a ligand (agonist) to a receptor and inhibits signal transduction into the cell via the receptor.
さらに、本発明は以下の少なくとも1つの箇所のアミノ酸がヒスチジン又は非天然アミノ酸に置換された抗体を提供する。なお、アミノ酸位置はKabatナンバリング(Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest.NIH)で示している。 Furthermore, the present invention provides an antibody in which at least one of the following amino acids is replaced with histidine or an unnatural amino acid. The amino acid positions are indicated by Kabat numbering (Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest. NIH).
重鎖:H27、H31、H32、H33、H35、H50、H58、H59、H61、H62、H63、H64、H65、H99、H100b、H102
軽鎖:L24、L27、L28、L32、L53、L54、L56、L90、L92、L94
Heavy chain: H27, H31, H32, H33, H35, H50, H58, H59, H61, H62, H63, H64, H65, H99, H100b, H102
Light chain: L24, L27, L28, L32, L53, L54, L56, L90, L92, L94
これらの改変箇所のうち、H32、H61、L53、L90、L94は普遍性の高い改変箇所と考えられる。 Of these modified parts, H32, H61, L53, L90, and L94 are considered to be highly universal modified parts.
又、特に限定されないが、抗原がIL-6受容体(例えば、ヒトIL-6受容体)の場合の好ましい改変箇所として以下の箇所を挙げることができる。 Further, although not particularly limited, the following sites can be mentioned as preferable modification sites when the antigen is an IL-6 receptor (for example, human IL-6 receptor).
重鎖:H27、H31、H32、H35、H50、H58、H61、H62、H63、H64、H65、H100b、H102
軽鎖:L24、L27、L28、L32、L53、L56、L90、L92、L94
Heavy chain: H27, H31, H32, H35, H50, H58, H61, H62, H63, H64, H65, H100b, H102
Light chain: L24, L27, L28, L32, L53, L56, L90, L92, L94
複数の箇所を組み合わせてヒスチジン又は非天然アミノ酸に置換する場合の好ましい組み合わせの具体例としては、例えば、H27、H31、H35の組み合わせ、H27、H31、H32、H35、H58、H62、H102の組み合わせ、L32、L53の組み合わせ、L28、L32、L53の組み合わせ等を挙げることができる。さらに、重鎖と軽鎖の置換箇所の好ましい組み合わせの例としては、H27、H31、L32、L53の組み合わせを挙げることができる。 Specific examples of preferable combinations when a plurality of sites are combined and replaced with histidine or an unnatural amino acid include, for example, a combination of H27, H31 and H35, a combination of H27, H31, H32, H35, H58, H62 and H102. The combination of L32 and L53, the combination of L28, L32 and L53, etc. can be mentioned. Furthermore, examples of preferred combinations of heavy chain and light chain substitution sites include combinations of H27, H31, L32, and L53.
又、特に限定されないが、抗原がIL-6(例えば、ヒトIL-6)の場合の好ましい改変箇所として以下の箇所を挙げることができる。 Further, although not particularly limited, the following sites can be mentioned as preferable modification sites when the antigen is IL-6 (for example, human IL-6).
重鎖:H32、H59、H61、H99
軽鎖:L53、L54、L90、L94
Heavy chain: H32, H59, H61, H99
Light chain: L53, L54, L90, L94
又、特に限定されないが、抗原がIL-31受容体(例えば、ヒトIL-31受容体)の場合の好ましい改変箇所としてH33を挙げることができる。 Further, although not particularly limited, H33 can be mentioned as a preferable modification site when the antigen is an IL-31 receptor (for example, a human IL-31 receptor).
本発明の抗原結合分子が認識する抗原は如何なる抗原でもよい。本発明の抗体が認識する抗原の具体的な例としては上述の受容体蛋白質(膜結合型受容体、可溶型受容体)、細胞表面マーカーなどの膜抗原やサイトカインなどの可溶型抗原、例えば、IL-1、IL-2、IL-3、IL-4、IL-5、IL-6、IL-7、IL-8、IL-9、IL-10、IL-11、IL-12、IL-15、IL-31、IL-23、IL-2受容体、IL-6受容体、OSM受容体、gp130、IL-5受容体、CD40、CD4、Fas、オステオポンチン、CRTH2、CD26、PDGF-D、CD20、単球走化活性因子、CD23、TNF-α、HMGB-1、α4インテグリン、ICAM-1、CCR2、CD11a、CD3、IFNγ、BLyS、HLA-DR、TGF-β、CD52、IL-31受容体などを挙げることができる。 The antigen recognized by the antigen-binding molecule of the present invention may be any antigen. Specific examples of the antigen recognized by the antibody of the present invention include the above-mentioned receptor proteins (membrane-bound receptor, soluble receptor), membrane antigens such as cell surface markers, and soluble antigens such as cytokines. For example, IL-1, IL-2, IL-3, IL-4, IL-5, IL-6, IL-7, IL-8, IL-9, IL-10, IL-11, IL-12, IL-15, IL-31, IL-23, IL-2 receptor, IL-6 receptor, OSM receptor, gp130, IL-5 receptor, CD40, CD4, Fas, Osteopontin, CRTH2, CD26, PDGF- D, CD20, monocytic activator, CD23, TNF-α, HMGB-1, α4 integrin, ICAM-1, CCR2, CD11a, CD3, IFNγ, BLyS, HLA-DR, TGF-β, CD52, IL- 31 Receptors can be mentioned.
特に好ましい抗原としては、IL-6受容体を挙げることができる。 Particularly preferred antigens include IL-6 receptor.
本発明の抗原結合分子については上述の通りである。 The antigen-binding molecule of the present invention is as described above.
本発明において抗原結合分子の好ましい態様として、抗体を挙げることができる。抗原結合活性とFcRn結合領域を有する抗体の例として、IgG抗体を挙げることができる。抗体としてIgG抗体を用いる場合、その種類は限定されず、IgG1、IgG2、IgG3、IgG4などを用いることが可能である。 An antibody can be mentioned as a preferred embodiment of the antigen-binding molecule in the present invention. An IgG antibody can be mentioned as an example of an antibody having an antigen-binding activity and an FcRn-binding region. When an IgG antibody is used as the antibody, the type is not limited, and IgG1, IgG2, IgG3, IgG4 and the like can be used.
本発明の抗体の由来は特に限定されず、如何なる由来の抗体でもよく、例えば、マウス抗体、ヒト抗体、ラット抗体、ウサギ抗体、ヤギ抗体、ラクダ抗体などを用いることができる。さらに、例えば、上述のキメラ抗体、中でもヒト化抗体などのアミノ酸配列を置換した改変抗体でもよい。また、上述の二種特異性抗体、各種分子を結合させた抗体修飾物、抗体断片を含むポリペプチド、糖鎖改変抗体などであってもよい。 The origin of the antibody of the present invention is not particularly limited, and an antibody of any origin may be used. For example, a mouse antibody, a human antibody, a rat antibody, a rabbit antibody, a goat antibody, a camel antibody and the like can be used. Further, for example, the above-mentioned chimeric antibody, particularly a modified antibody in which the amino acid sequence of a humanized antibody or the like is substituted may be used. Further, the above-mentioned bispecific antibody, an antibody modified product in which various molecules are bound, a polypeptide containing an antibody fragment, a sugar chain modified antibody, or the like may be used.
キメラ抗体の作製は公知であり、例えば、ヒト−マウスキメラ抗体の場合、抗体V領域をコードするDNAとヒト抗体C領域をコードするDNAと連結し、これを発現ベクターに組み込んで宿主に導入し産生させることによりキメラ抗体を得ることができる。 The production of a chimeric antibody is known. For example, in the case of a human-mouse chimeric antibody, a DNA encoding the antibody V region and a DNA encoding the human antibody C region are ligated, and this is incorporated into an expression vector and introduced into a host. A chimeric antibody can be obtained by producing it.
「ヒト化抗体」とは、再構成(reshaped)ヒト抗体とも称される、ヒト以外の哺乳動物由来の抗体、例えばマウス抗体の相補性決定領域(CDR;complementarity determining region)をヒト抗体のCDRへ移植したものである。CDRを同定するための方法は公知である(Kabat et al., Sequence of Proteins of Immunological Interest (1987), National Institute of Health, Bethesda, Md.; Chothia et al., Nature (1989) 342: 877)。また、その一般的な遺伝子組換え手法も公知である(欧州特許出願公開番号EP 125023号公報、WO 96/02576 号公報参照)。ヒト化抗体は公知の方法により、例えば、マウス抗体のCDRを決定し、該CDRとヒト抗体のフレームワーク領域(framework region;FR)とが連結された抗体をコードするDNAを取得し、ヒト化抗体を通常の発現ベクターを用いた系により産生することができる。このようなDNAは、CDR及びFR両方の末端領域にオーバーラップする部分を有するように作製した数個のオリゴヌクレオチドをプライマーとして用いてPCR法により合成することができる(WO98/13388号公報に記載の方法を参照)。CDRを介して連結されるヒト抗体のFRは、CDRが良好な抗原結合部位を形成するように選択される。必要に応じ、再構成ヒト抗体のCDRが適切な抗原結合部位を形成するように、抗体の可変領域におけるFRのアミノ酸を改変してもよい(Sato et al., Cancer Res. (1993) 53: 10.01-6)。改変できるFR中のアミノ酸残基には、抗原に直接、非共有結合により結合する部分(Amit et al., Science (1986) 233: 747-53)、CDR構造に影響または作用する部分(Chothia et al., J. Mol. Biol. (1987) 196: 901-17)及びVH-VL相互作用に関連する部分(EP239400号特許公報)が含まれる。 A "humanized antibody" is an antibody derived from a non-human mammal, which is also called a reshaped human antibody, for example, a mouse antibody's complementarity determining region (CDR) is transferred to the human antibody's CDR. It is a transplant. Methods for identifying CDRs are known (Kabat et al., Sequence of Proteins of Immunological Interest (1987), National Institute of Health, Bethesda, Md .; Chothia et al., Nature (1989) 342: 877). .. The general gene recombination method is also known (see European Patent Application Publication No. EP 125023, WO 96/02576). For the humanized antibody, for example, the CDR of the mouse antibody is determined by a known method, and the DNA encoding the antibody in which the CDR and the framework region (FR) of the human antibody are linked is obtained and humanized. Antibodies can be produced by a system using a conventional expression vector. Such DNA can be synthesized by the PCR method using several oligonucleotides prepared so as to have overlapping portions in both CDR and FR terminal regions as primers (described in WO98 / 13388). See method). The FR of a human antibody linked via a CDR is selected so that the CDR forms a good antigen binding site. If desired, the amino acids of FR in the variable region of the antibody may be modified so that the CDRs of the reconstituted human antibody form the appropriate antigen binding site (Sato et al., Cancer Res. (1993) 53: 10.01-6). Amino acid residues in the modifiable FR include those that directly bind to the antigen by non-covalent bonds (Amit et al., Science (1986) 233: 747-53) and those that affect or act on the CDR structure (Chothia et. Al., J. Mol. Biol. (1987) 196: 901-17) and parts related to VH-VL interaction (EP239400 Patent Publication) are included.
本発明における抗体がキメラ抗体またはヒト化抗体である場合には、これらの抗体のC領域は、好ましくはヒト抗体由来のものが使用される。例えばH鎖では、Cγ1、Cγ2、Cγ3、Cγ4などを、L鎖ではCκ、Cλなどを使用することができる。また、FcγレセプターやFcRnへの結合を増大あるいは低減させるために、抗体の安定性または抗体の産生を改善するために、ヒト抗体C領域を必要に応じアミノ酸変異を導入してもよい。本発明におけるキメラ抗体は、好ましくはヒト以外の哺乳動物由来抗体の可変領域とヒト抗体由来の定常領域とからなる。一方、ヒト化抗体は、好ましくはヒト以外の哺乳動物由来抗体のCDRと、ヒト抗体由来のFRおよびC領域とからなる。ヒト抗体由来の定常領域は、FcRn結合領域を含んでいることが好ましく、そのような抗体の例として、IgG(IgG1、IgG2、IgG3、IgG4)を挙げることができる。本発明におけるヒト化抗体に用いられる定常領域は、どのアイソタイプに属する抗体の定常領域であってもよい。好ましくは、ヒトIgGの定常領域が用いられるが、これに限定されるものではない。また、ヒト化抗体に利用されるヒト抗体由来のFRも特に限定されず、どのアイソタイプに属する抗体のものであってもよい。 When the antibody in the present invention is a chimeric antibody or a humanized antibody, the C region of these antibodies is preferably derived from a human antibody. For example, Cγ1, Cγ2, Cγ3, Cγ4 and the like can be used in the H chain, and Cκ, Cλ and the like can be used in the L chain. In addition, amino acid mutations may be introduced into the human antibody C region as necessary in order to improve the stability of the antibody or the production of the antibody in order to increase or decrease the binding to the Fcγ receptor or FcRn. The chimeric antibody in the present invention preferably comprises a variable region of a non-human mammalian-derived antibody and a constant region derived from a human antibody. On the other hand, the humanized antibody preferably consists of CDRs of non-human mammalian-derived antibodies and FR and C regions derived from human antibodies. The constant region derived from a human antibody preferably contains an FcRn binding region, and examples of such an antibody include IgG (IgG1, IgG2, IgG3, IgG4). The constant region used for the humanized antibody in the present invention may be the constant region of an antibody belonging to any isotype. Preferably, a constant region of human IgG is used, but is not limited thereto. Further, the FR derived from the human antibody used for the humanized antibody is not particularly limited, and may be an antibody belonging to any isotype.
本発明におけるキメラ抗体及びヒト化抗体の可変領域及び定常領域は、元の抗体の結合特異性を示す限り、欠失、置換、挿入及び/または付加等により改変されていてもよい。 The variable region and constant region of the chimeric antibody and the humanized antibody in the present invention may be modified by deletion, substitution, insertion and / or addition as long as they show the binding specificity of the original antibody.
ヒト由来の配列を利用したキメラ抗体及びヒト化抗体は、ヒト体内における免疫原性が低下しているため、治療目的などでヒトに投与する場合に有用と考えられる。 Chimeric antibodies and humanized antibodies using human-derived sequences are considered to be useful when administered to humans for therapeutic purposes because their immunogenicity in the human body is reduced.
本発明の抗体は如何なる方法により得られてもよく、例えば、本来はpH5.8での抗原結合活性がpH7.4での抗原結合活性より高い抗体又は抗原結合活性が同程度である抗体を、上述のヒスチジンへの置換等により、人為的にpH5.8での抗原結合活性をpH7.4での抗原結合活性より低くしてもよいし、又、以下に示す抗体ライブラリーやハイブリドーマから得られる複数の抗体の中からpH5.8での抗原結合活性がpH7.4での抗原結合活性より低い抗体をスクリーニングすることで選択してもよい。 The antibody of the present invention may be obtained by any method, for example, an antibody having an antigen-binding activity at pH 5.8 higher than that at pH 7.4 or an antibody having the same antigen-binding activity. The antigen-binding activity at pH 5.8 may be artificially made lower than the antigen-binding activity at pH 7.4 by the above-mentioned substitution with histidine, or it can be obtained from the antibody library or hybridoma shown below. It may be selected from a plurality of antibodies by screening an antibody having an antigen-binding activity at pH 5.8 lower than that at pH 7.4.
抗体中のアミノ酸をヒスチジンに置換する場合、ヒスチジン変異導入前の抗体のH鎖又はL鎖のアミノ酸配列は既知の配列を用いることも可能であり、又、当業者に公知の方法で新しく取得した抗体のアミノ酸配列を用いることも可能である。例えば、抗体は、抗体ライブラリーから取得することも可能であるし、モノクローナル抗体を産生するハイブリドーマから抗体をコードする遺伝子をクローニングして取得することも可能である。 When substituting the amino acid in the antibody with histidine, it is possible to use a known sequence for the amino acid sequence of the H chain or L chain of the antibody before the introduction of the histidine mutation, or newly obtained by a method known to those skilled in the art. It is also possible to use the amino acid sequence of the antibody. For example, the antibody can be obtained from an antibody library, or can be obtained by cloning a gene encoding an antibody from a hybridoma that produces a monoclonal antibody.
抗体ライブラリーについては既に多くの抗体ライブラリーが公知になっており、又、抗体ライブラリーの作製方法も公知であるので、当業者は適宜抗体ライブラリーを入手することが可能である。例えば、抗体ファージライブラリーについては、Clackson et al., Nature 1991, 352: 624-8、Marks et al., J. Mol. Biol. 1991, 222: 581-97、Waterhouses et al., Nucleic Acids Res. 1993, 21: 2265-6、Griffiths et al., EMBO J. 1994, 13: 324.0-60、Vaughan et al., Nature Biotechnology 1996, 14: 309-14、及び特表平20−504970号公報等の文献を参照することができる。その他、真核細胞をライブラリーとする方法(WO95/15393号パンフレット)やリボソーム提示法等の公知の方法を用いることが可能である。さらに、ヒト抗体ライブラリーを用いて、パンニングによりヒト抗体を取得する技術も知られている。例えば、ヒト抗体の可変領域を一本鎖抗体(scFv)としてファージディスプレイ法によりファージの表面に発現させ、抗原に結合するファージを選択することができる。選択されたファージの遺伝子を解析すれば、抗原に結合するヒト抗体の可変領域をコードするDNA配列を決定することができる。抗原に結合するscFvのDNA配列が明らかになれば、当該配列を元に適当な発現ベクターを作製し、ヒト抗体を取得することができる。これらの方法は既に周知であり、WO92/01047、WO92/20791、WO93/06213、WO93/11236、WO93/19172、WO95/01438、WO95/15388を参考にすることができる。 As for the antibody library, many antibody libraries are already known, and the method for producing the antibody library is also known, so that a person skilled in the art can appropriately obtain the antibody library. For example, for antibody phage libraries, Clackson et al., Nature 1991, 352: 624-8, Marks et al., J. Mol. Biol. 1991, 222: 581-97, Waterhouses et al., Nucleic Acids Res. 1993, 21: 2265-6, Griffiths et al., EMBO J. 1994, 13: 324.0-60, Vaughan et al., Nature Biotechnology 1996, 14: 309-14, and Gazette No. 20-50 4970, etc. The literature can be referred to. In addition, known methods such as a method using eukaryotic cells as a library (Pamphlet WO 95/15393) and a ribosome presentation method can be used. Further, a technique for obtaining a human antibody by panning using a human antibody library is also known. For example, a phage that binds to an antigen can be selected by expressing the variable region of a human antibody as a single chain antibody (scFv) on the surface of the phage by the phage display method. By analyzing the genes of the selected phage, the DNA sequence encoding the variable region of the human antibody that binds to the antigen can be determined. Once the DNA sequence of scFv that binds to the antigen is clarified, an appropriate expression vector can be prepared based on the sequence and a human antibody can be obtained. These methods are already well known, and WO92 / 01047, WO92 / 20791, WO93 / 06213, WO93 / 11236, WO93 / 19172, WO95 / 01438, WO95 / 15388 can be referred to.
ハイブリドーマから抗体をコードする遺伝子を取得する方法は、基本的には公知技術を使用し、所望の抗原または所望の抗原を発現する細胞を感作抗原として使用して、これを通常の免疫方法にしたがって免疫し、得られる免疫細胞を通常の細胞融合法によって公知の親細胞と融合させ、通常のスクリーニング法により、モノクローナルな抗体産生細胞(ハイブリドーマ)をスクリーニングし、得られたハイブリドーマのmRNAから逆転写酵素を用いて抗体の可変領域(V領域)のcDNAを合成し、これを所望の抗体定常領域(C領域)をコードするDNAと連結することにより得ることができる。 The method for obtaining a gene encoding an antibody from a hybridoma basically uses a known technique, uses a desired antigen or a cell expressing the desired antigen as a sensitizing antigen, and uses this as a normal immune method. Therefore, the immune cells obtained by immunization are fused with known parent cells by a normal cell fusion method, monoclonal antibody-producing cells (hybridoma) are screened by a normal screening method, and reverse transcription from the obtained hybridoma mRNA. It can be obtained by synthesizing a cDNA in the variable region (V region) of an antibody using an enzyme and ligating it with a DNA encoding a desired antibody constant region (C region).
より具体的には、特に以下の例示に限定されないが、上記のH鎖及びL鎖をコードする抗体遺伝子を得るための感作抗原は、免疫原性を有する完全抗原と、免疫原性を示さないハプテン等を含む不完全抗原の両方を含む。例えば、目的タンパク質の全長タンパク質、又は部分ペプチドなどを用いることができる。その他、多糖類、核酸、脂質等から構成される物質が抗原となり得ることが知られており、本発明の抗体の抗原は特に限定されるものではない。抗原の調製は、当業者に公知の方法により行うことができ、例えば、バキュロウィルスを用いた方法(例えば、WO98/46777など)などに準じて行うことができる。ハイブリドーマの作製は、たとえば、ミルステインらの方法(G. Kohler and C. Milstein, Methods Enzymol. 1981, 73: 3-46)等に準じて行うことができる。抗原の免疫原性が低い場合には、アルブミン等の免疫原性を有する巨大分子と結合させ、免疫を行えばよい。また、必要に応じ抗原を他の分子と結合させることにより可溶性抗原とすることもできる。膜抗原(例えば、受容体など)のような膜貫通分子を抗原として用いる場合、膜抗原の細胞外領域部分を断片として用いたり、膜貫通分子を細胞表面上に発現する細胞を免疫原として使用することも可能である。 More specifically, although not particularly limited to the following examples, the sensitizing antigen for obtaining the antibody gene encoding the above H chain and L chain shows a complete antigen having immunogenicity and an immunogenicity. Contains both incomplete antigens, including no haptens and the like. For example, a full-length protein of the target protein, a partial peptide, or the like can be used. In addition, it is known that a substance composed of polysaccharides, nucleic acids, lipids and the like can serve as an antigen, and the antigen of the antibody of the present invention is not particularly limited. The antigen can be prepared by a method known to those skilled in the art, and can be prepared according to, for example, a method using baculovirus (for example, WO98 / 46777). The hybridoma can be produced, for example, according to the method of Milstein et al. (G. Kohler and C. Milstein, Methods Enzymol. 1981, 73: 3-46). When the immunogenicity of the antigen is low, it may be immunized by binding to a macromolecule having immunogenicity such as albumin. Further, if necessary, the antigen can be made into a soluble antigen by binding to another molecule. When a transmembrane molecule such as a membrane antigen (for example, a receptor) is used as an antigen, the extracellular region portion of the membrane antigen is used as a fragment, or a cell expressing the transmembrane molecule on the cell surface is used as an immunogen. It is also possible to do.
抗体産生細胞は、上述の適当な感作抗原を用いて動物を免疫化することにより得ることができる。または、抗体を産生し得るリンパ球をin vitroで免疫化して抗体産生細胞とすることもできる。免疫化する動物としては、各種哺乳動物を使用できるが、ゲッ歯目、ウサギ目、霊長目の動物が一般的に用いられる。マウス、ラット、ハムスター等のゲッ歯目、ウサギ等のウサギ目、カニクイザル、アカゲザル、マントヒヒ、チンパンジー等のサル等の霊長目の動物を例示することができる。その他、ヒト抗体遺伝子のレパートリーを有するトランスジェニック動物も知られており、このような動物を使用することによりヒト抗体を得ることもできる(WO96/34096; Mendez et al., Nat. Genet. 1997, 15: 146-56参照)。このようなトランスジェニック動物の使用に代えて、例えば、ヒトリンパ球をin vitroで所望の抗原または所望の抗原を発現する細胞で感作し、感作リンパ球をヒトミエローマ細胞、例えばU266と融合させることにより、抗原への結合活性を有する所望のヒト抗体を得ることもできる(特公平1-59878号公報参照)。また、ヒト抗体遺伝子の全てのレパートリーを有するトランスジェニック動物を所望の抗原で免疫することで所望のヒト抗体を取得することができる(WO93/12227、WO92/03918、WO94/02602、WO96/34096、WO96/33735参照)。 Antibody-producing cells can be obtained by immunizing an animal with the appropriate sensitizing antigen described above. Alternatively, lymphocytes capable of producing antibodies can be immunized in vitro to obtain antibody-producing cells. As the animal to be immunized, various mammals can be used, but animals of the order Lagomorpha, Lagomorpha, and Primates are generally used. Examples thereof include mouse, rat, hamster and other mouse eyes, rabbit and other rabbit eyes, cynomolgus monkey, rhesus monkey, hamadryas baboon and chimpanzee and other primate animals. In addition, transgenic animals having a repertoire of human antibody genes are also known, and human antibodies can be obtained by using such animals (WO96 / 34096; Mendez et al., Nat. Genet. 1997, 15: See 146-56). Instead of using such transgenic animals, for example, human lymphocytes are sensitized in vitro with the desired antigen or cells expressing the desired antigen, and the sensitized lymphocytes are fused with human myeloma cells, such as U266. Thereby, a desired human antibody having an antigen-binding activity can also be obtained (see Japanese Patent Publication No. 1-59878). In addition, a desired human antibody can be obtained by immunizing a transgenic animal having the entire repertoire of human antibody genes with a desired antigen (WO93 / 12227, WO92 / 03918, WO94 / 02602, WO96 / 34096, See WO 96/33735).
動物の免疫化は、例えば、感作抗原をPhosphate-Buffered Saline(PBS)または生理食塩水等で適宜希釈、懸濁し、必要に応じてアジュバントを混合して乳化した後、動物の腹腔内または皮下に注射することにより行われる。その後、好ましくは、フロイント不完全アジュバントに混合した感作抗原を4〜21日毎に数回投与する。抗体の産生の確認は、動物の血清中の目的とする抗体力価を慣用の方法により測定することにより行われ得る。 For immunization of animals, for example, the sensitizing antigen is appropriately diluted and suspended with Phosphate-Buffered Saline (PBS) or physiological saline, and if necessary, an adjuvant is mixed and emulsified, and then intraperitoneally or subcutaneously of the animal. It is done by injecting into. Then, preferably, the sensitizing antigen mixed with Freund's incomplete adjuvant is administered several times every 4 to 21 days. Confirmation of antibody production can be performed by measuring the antibody titer of interest in animal serum by a conventional method.
ハイブリドーマは、所望の抗原で免疫化した動物またはリンパ球より得られた抗体産生細胞を、慣用の融合剤(例えば、ポリエチレングリコール)を使用してミエローマ細胞と融合して作成することができる(Goding, Monoclonal Antibodies: Principles and Practice, Academic Press, 1986, 59-103)。必要に応じハイブリドーマ細胞を培養・増殖し、免疫沈降、放射免疫分析(RIA)、酵素結合免疫吸着分析(ELISA)等の公知の分析法により該ハイブリドーマより産生される抗体の結合特異性を測定する。その後、必要に応じ、目的とする特異性、親和性または活性が測定された抗体を産生するハイブリドーマを限界希釈法等の手法によりサブクローニングすることもできる。 Hybridomas can be made by fusing antibody-producing cells obtained from animals or lymphocytes immunized with the desired antigen with myeloma cells using conventional fusion agents (eg, polyethylene glycol) (Goding). , Monoclonal Antibodies: Principles and Practice, Academic Press, 1986, 59-103). If necessary, hybridoma cells are cultured and proliferated, and the binding specificity of the antibody produced by the hybridoma is measured by known analytical methods such as immunoprecipitation, radioimmunoassay (RIA), and enzyme-linked immunosorbent assay (ELISA). .. Then, if necessary, a hybridoma producing an antibody whose specificity, affinity or activity of interest has been measured can be subcloned by a method such as a limiting dilution method.
続いて、選択された抗体をコードする遺伝子をハイブリドーマまたは抗体産生細胞(感作リンパ球等)から、抗体に特異的に結合し得るプローブ(例えば、抗体定常領域をコードする配列に相補的なオリゴヌクレオチド等)を用いてクローニングすることができる。また、mRNAからRT-PCRによりクローニングすることも可能である。免疫グロブリンは、IgA、IgD、IgE、IgG及びIgMの5つの異なるクラスに分類される。さらに、これらのクラスは幾つかのサブクラス(アイソタイプ)(例えば、IgG-1、IgG-2、IgG-3、及びIgG-4;IgA-1及びIgA-2等)に分けられる。本発明において抗体の製造に使用するH鎖及びL鎖は、これらいずれのクラス及びサブクラスに属する抗体に由来するものであってもよく、特に限定されないが、IgGは特に好ましいものである。 Subsequently, a probe (eg, an oligo complementary to the sequence encoding the antibody constant region) capable of specifically binding the selected antibody-encoding gene from a hybridoma or antibody-producing cell (sensitized lymphocyte, etc.) to the antibody (eg, an oligo complementary to the sequence encoding the antibody constant region). It can be cloned using (nucleotides, etc.). It is also possible to clone from mRNA by RT-PCR. Immunoglobulins are classified into five different classes: IgA, IgD, IgE, IgG and IgM. Further, these classes are divided into several subclasses (isotypes) (eg, IgG-1, IgG-2, IgG-3, and IgG-4; IgA-1 and IgA-2, etc.). The H chain and L chain used in the production of the antibody in the present invention may be derived from an antibody belonging to any of these classes and subclasses, and are not particularly limited, but IgG is particularly preferable.
ここで、H鎖及びL鎖をコードする遺伝子を遺伝子工学的手法により改変することも可能である。例えば、マウス抗体、ラット抗体、ウサギ抗体、ハムスター抗体、ヒツジ抗体、ラクダ抗体等の抗体について、ヒトに対する異種免疫原性を低下させること等を目的として、人為的に改変した遺伝子組換え型抗体、例えば、キメラ抗体、ヒト化抗体等を適宜作製することができる。キメラ抗体は、ヒト以外の哺乳動物、例えば、マウス抗体のH鎖、L鎖の可変領域とヒト抗体のH鎖、L鎖の定常領域からなる抗体であり、マウス抗体の可変領域をコードするDNAをヒト抗体の定常領域をコードするDNAと連結し、これを発現ベクターに組み込んで宿主に導入し産生させることにより得ることができる。ヒト化抗体は、再構成(reshaped)ヒト抗体とも称され、ヒト以外の哺乳動物、たとえばマウス抗体の相補性決定領域(CDR; complementary determining region)を連結するように設計したDNA配列を、末端部にオーバーラップする部分を有するように作製した数個のオリゴヌクレオチドからPCR法により合成する。得られたDNAをヒト抗体定常領域をコードするDNAと連結し、次いで発現ベクターに組み込んで、これを宿主に導入し産生させることにより得られる(EP239400; WO96/02576参照)。CDRを介して連結されるヒト抗体のFRは、相補性決定領域が良好な抗原結合部位を形成するものが選択される。必要に応じ、再構成ヒト抗体の相補性決定領域が適切な抗原結合部位を形成するように抗体の可変領域のフレームワーク領域のアミノ酸を置換してもよい(K. Sato et al., Cancer Res. 1993, 53: 10.01-10.06)。 Here, it is also possible to modify the genes encoding the H chain and the L chain by a genetic engineering technique. For example, a genetically modified antibody obtained by artificially modifying an antibody such as a mouse antibody, a rat antibody, a rabbit antibody, a hamster antibody, a sheep antibody, or a camel antibody for the purpose of reducing heterologous immunogenicity to humans. For example, a chimeric antibody, a humanized antibody and the like can be appropriately produced. A chimeric antibody is an antibody consisting of a non-human mammal, for example, a variable region of the H chain and L chain of a mouse antibody and a constant region of the H chain and L chain of a human antibody, and is a DNA encoding the variable region of a mouse antibody. Can be obtained by ligating a DNA encoding a constant region of a human antibody, incorporating it into an expression vector, introducing it into a host, and producing it. Humanized antibodies, also referred to as reshaped human antibodies, have DNA sequences designed to link complementarity determining regions (CDRs) of non-human mammals, such as mouse antibodies. Synthesize by PCR from several oligonucleotides prepared to have overlapping portions. It is obtained by ligating the obtained DNA to the DNA encoding the human antibody constant region, then incorporating it into an expression vector, introducing it into a host and producing it (see EP239400; WO 96/02576). The FR of the human antibody linked via CDR is selected so that the complementarity determining regions form a good antigen-binding site. If desired, the amino acids in the framework regions of the variable region of the antibody may be replaced so that the complementarity determining regions of the reconstituted human antibody form the appropriate antigen binding site (K. Sato et al., Cancer Res). . 1993, 53: 10.01-10.06).
上述のヒト化以外に、例えば、抗原との結合性等の抗体の生物学的特性を改善するために改変を行うことも考えられる。本発明における改変は、部位特異的突然変異(例えば、Kunkel (1910.0) Proc. Natl. Acad. Sci. USA 82: 488参照)、PCR変異、カセット変異等の方法により行うことができる。一般に、生物学的特性の改善された抗体変異体は70%以上、より好ましくは80%以上、さらに好ましくは90%以上(例えば、95%以上、97%、98%、99%等)のアミノ酸配列相同性及び/または類似性を、元となった抗体の可変領域のアミノ酸配列に対して有する。本明細書において、配列の相同性及び/または類似性は、配列相同性が最大の値を取るように必要に応じ配列を整列化、及びギャップ導入した後、元となった抗体残基と相同(同じ残基)または類似(一般的なアミノ酸の側鎖の特性に基き同じグループに分類されるアミノ酸残基)するアミノ酸残基の割合として定義される。通常、天然のアミノ酸残基は、その側鎖の性質に基づいて
(1)疎水性:アラニン、イソロイシン、バリン、メチオニン及びロイシン;
(2)中性親水性:アスパラギン、グルタミン、システイン、スレオニン及びセリン;
(3)酸性:アスパラギン酸及びグルタミン酸;
(4)塩基性:アルギニン、ヒスチジン及びリジン;
(5)鎖の配向に影響する残基:グリシンおよびプロリン;ならびに
(6)芳香族性:チロシン、トリプトファン及びフェニルアラニン
のグループに分類される。
In addition to the above-mentioned humanization, modifications may be made to improve the biological properties of the antibody, such as binding to an antigen. Modifications in the present invention can be made by site-specific mutations (see, eg, Kunkel (1910.0) Proc. Natl. Acad. Sci. USA 82: 488), PCR mutations, cassette mutations and the like. In general, antibody variants with improved biological properties contain 70% or more, more preferably 80% or more, and even more preferably 90% or more (eg, 95% or more, 97%, 98%, 99%, etc.) amino acids. It has sequence homology and / or similarity to the amino acid sequence of the variable region of the underlying antibody. As used herein, sequence homology and / or similarity is homologous to the original antibody residue after the sequences have been aligned and gap-introduced as necessary to maximize sequence homology. It is defined as the percentage of amino acid residues that are (same residue) or similar (amino acid residues that are classified in the same group based on the characteristics of the side chains of common amino acids). Natural amino acid residues are usually based on the nature of their side chains.
(1) Hydrophobicity: alanine, isoleucine, valine, methionine and leucine;
(2) Neutral hydrophilicity: asparagine, glutamine, cysteine, threonine and serine;
(3) Acidity: aspartic acid and glutamic acid;
(4) Basic: arginine, histidine and lysine;
(5) Residues affecting chain orientation: glycine and proline; and
(6) Aromaticity: Classified into the groups of tyrosine, tryptophan and phenylalanine.
通常、H鎖及びL鎖の可変領域中に存在する全部で6つの相補性決定領域(超可変部;CDR)が相互作用し、抗体の抗原結合部位を形成している。このうち1つの可変領域であっても全結合部位を含むものよりは低い親和性となるものの、抗原を認識し、結合する能力があることが知られている。従って、本発明のH鎖及びL鎖をコードする抗体遺伝子は、該遺伝子によりコードされるポリペプチドが所望の抗原との結合性を維持していればよく、H鎖及びL鎖の各々の抗原結合部位を含む断片部分をコードしていればよい。 Normally, a total of six complementarity determining regions (supervariable regions; CDRs) present in the variable regions of the H and L chains interact to form the antigen-binding site of the antibody. It is known that even one of these variable regions has a lower affinity than that containing a full binding site, but has the ability to recognize and bind to an antigen. Therefore, the antibody gene encoding the H chain and the L chain of the present invention only needs to maintain the binding property of the polypeptide encoded by the gene to the desired antigen, and the antigens of the H chain and the L chain are each. It suffices to encode the fragment portion including the binding site.
重鎖可変領域は、上述のように、通常3つのCDR領域と4つのFR領域によって構成されている。本発明の好ましい態様において「改変」に供するアミノ酸残基としては、例えば、CDR領域あるいはFR領域に位置するアミノ酸残基の中から適宜選択することができる。一般的にCDR領域のアミノ酸残基の改変は、抗原に対する結合能を低下させる場合がある。従って、本発明において「改変」に供するアミノ酸残基としては、特に限定されるものではないが、FR領域に位置するアミノ酸残基の中から適宜選択することが好ましい。CDRであっても改変によって結合能が低下しないことが確認された場合は、その箇所を選択することが可能である。また、ヒトもしくはマウス等の生物において、抗体の可変領域のFRとして利用可能な配列を、当業者であれば、公共のデータベース等を利用して適宜取得することができる。 As described above, the heavy chain variable region is usually composed of three CDR regions and four FR regions. As the amino acid residue to be subjected to "modification" in the preferred embodiment of the present invention, for example, an amino acid residue located in the CDR region or FR region can be appropriately selected. In general, modification of amino acid residues in the CDR regions may reduce the ability to bind to an antigen. Therefore, the amino acid residue to be used for "modification" in the present invention is not particularly limited, but it is preferable to appropriately select from the amino acid residues located in the FR region. If it is confirmed that the binding ability is not reduced by the modification even in the CDR, it is possible to select the site. Further, in an organism such as human or mouse, a sequence that can be used as FR of the variable region of the antibody can be appropriately obtained by a person skilled in the art using a public database or the like.
さらに、本発明は本発明の抗体をコードする遺伝子を提供する。本発明の抗体をコードする遺伝子は如何なる遺伝子でもよく、DNA、RNA、その他核酸類似体などでもよい。 Furthermore, the present invention provides genes encoding the antibodies of the present invention. The gene encoding the antibody of the present invention may be any gene, such as DNA, RNA, or other nucleic acid analog.
さらに本発明は、上記遺伝子を有する宿主細胞を提供する。該宿主細胞は、特に制限されず、例えば、大腸菌や種々の動物細胞などを挙げることができる。宿主細胞は、例えば、本発明の抗体の製造や発現のための産生系として使用することができる。ポリペプチド製造のための産生系には、in vitroおよびin vivoの産生系がある。in vitroの産生系としては、真核細胞を使用する産生系及び原核細胞を使用する産生系が挙げられる。 Furthermore, the present invention provides a host cell having the above gene. The host cell is not particularly limited, and examples thereof include Escherichia coli and various animal cells. The host cell can be used, for example, as a production system for the production and expression of the antibody of the present invention. Production systems for the production of polypeptides include in vitro and in vivo production systems. Examples of the in vitro production system include a production system using eukaryotic cells and a production system using prokaryotic cells.
宿主細胞として使用できる真核細胞として、例えば、動物細胞、植物細胞、真菌細胞が挙げられる。動物細胞としては、哺乳類細胞、例えば、CHO(J. Exp. Med. (1995) 108: 94.0)、COS、HEK293、3T3、ミエローマ、BHK(baby hamster kidney)、HeLa、Vero等、両生類細胞、例えばアフリカツメガエル卵母細胞(Valle et al., Nature (1981) 291: 338-340)、及び昆虫細胞、例えば、Sf9、Sf21、Tn5が例示される。本発明の抗体の発現においては、CHO-DG44、CHO-DX11B、COS7細胞、HEK293細胞、BHK細胞が好適に用いられる。動物細胞において、大量発現を目的とする場合には特にCHO細胞が好ましい。宿主細胞へのベクターの導入は、例えば、リン酸カルシウム法、DEAEデキストラン法、カチオニックリボソームDOTAP(Boehringer Mannheim製)を用いた方法、エレクトロポレーション法、リポフェクションなどの方法で行うことが可能である。 Eukaryotic cells that can be used as host cells include, for example, animal cells, plant cells, and fungal cells. Animal cells include mammalian cells such as CHO (J. Exp. Med. (1995) 108: 94.0), COS, HEK293, 3T3, myeloma, BHK (baby hamster kidney), HeLa, Vero, and other amphibian cells. Xenopus laevis (Valle et al., Nature (1981) 291: 338-340), and insect cells such as Sf9, Sf21, Tn5 are exemplified. In the expression of the antibody of the present invention, CHO-DG44, CHO-DX11B, COS7 cells, HEK293 cells, and BHK cells are preferably used. In animal cells, CHO cells are particularly preferable for the purpose of large-scale expression. The vector can be introduced into a host cell by, for example, a calcium phosphate method, a DEAE dextran method, a method using a cationic ribosome DOTAP (manufactured by Boehringer Mannheim), an electroporation method, or a lipofection method.
植物細胞としては、例えば、ニコチアナ・タバカム(Nicotiana tabacum)由来の細胞およびウキクサ(Lemna minor)が蛋白質生産系として知られており、この細胞をカルス培養する方法により本発明の抗体を産生させることができる。真菌細胞としては、酵母、例えば、サッカロミセス(Saccharomyces)属の細胞(サッカロミセス・セレビシエ(Saccharomyces cerevisiae)、サッカロミセス・ポンベ(Saccharomyces pombe)等)、及び糸状菌、例えば、アスペルギルス(Aspergillus)属の細胞(アスペルギルス・ニガー(Aspergillus niger)等)を用いた蛋白質発現系が公知であり、本発明の抗体産生の宿主として利用できる。 As plant cells, for example, cells derived from Nicotiana tabacum and Duckweed (Lemna minor) are known as protein-producing systems, and the antibody of the present invention can be produced by a method of culturing these cells in callus. it can. Fungal cells include yeast, for example, cells of the genus Saccharomyces (Saccharomyces cerevisiae, Saccharomyces pombe, etc.), and filamentous fungi, for example, cells of the genus Aspergillus (Aspergillus). -A protein expression system using Niger (Aspergillus niger, etc.) is known and can be used as a host for the antibody production of the present invention.
原核細胞を使用する場合、細菌細胞を用いる産生系がある。細菌細胞としては、上述の大腸菌(E. coli)に加えて、枯草菌を用いた産生系が知られており、本発明の抗体産生に利用できる。 When using prokaryotic cells, there are production systems that use bacterial cells. As a bacterial cell, a production system using Bacillus subtilis in addition to the above-mentioned E. coli is known and can be used for antibody production of the present invention.
<スクリーニング方法>
本発明は抗原結合分子の酸性pHにおける抗原結合活性が中性pHにおける抗原結合活性よりも低い抗原結合分子をスクリーニングする方法を提供する。又、本発明は1分子で複数の抗原に結合することが可能な抗原結合分子のスクリーニング方法を提供する。又、本発明は血漿中滞留性に優れた抗原結合分子のスクリーニング方法を提供する。又、本発明は細胞外で抗原結合分子に結合した抗原を細胞内で解離する抗原結合分子のスクリーニング方法を提供する。又、本発明は抗原と結合した状態で細胞内に取り込まれ、抗原と結合していない状態で細胞外に放出される抗原結合分子のスクリーニング方法を提供する。又、本発明は血漿中抗原消失能が増加した抗原結合分子のスクリーニング方法を提供する。さらに、本発明は医薬組成物として用いる際に特に有用である抗原結合分子のスクリーニング方法を提供する。
<Screening method>
The present invention provides a method for screening an antigen-binding molecule whose antigen-binding activity at acidic pH is lower than that at neutral pH. The present invention also provides a method for screening an antigen-binding molecule capable of binding to a plurality of antigens with one molecule. The present invention also provides a method for screening an antigen-binding molecule having excellent plasma retention. The present invention also provides a method for screening an antigen-binding molecule that dissociates an antigen bound to the antigen-binding molecule extracellularly inside the cell. The present invention also provides a method for screening an antigen-binding molecule that is taken up into cells in a state of being bound to an antigen and released extracellularly in a state of not binding to an antigen. The present invention also provides a method for screening an antigen-binding molecule having an increased ability to eliminate antigen in plasma. Furthermore, the present invention provides a method for screening antigen-binding molecules, which is particularly useful when used as a pharmaceutical composition.
具体的には、本発明は以下の工程を含む抗原結合分子のスクリーニング方法を提供する。
(a) pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b) pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c) pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程。
Specifically, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5.
本発明のスクリーニング方法において、pH6.7〜pH10.0における抗原結合分子の抗原結合活性はpH6.7〜pH10.0の間の抗原結合活性であれば特に限定されないが、好ましい抗原結合活性として、pH7.0〜pH8.0の間の抗原結合活性を挙げることができ、より好ましい抗原結合活性としてpH7.4における抗原結合活性を挙げることができる。又、pH4.0〜pH6.5における抗原結合分子の抗原結合活性はpH4.0〜pH6.5の間の抗原結合活性であれば特に限定されないが、好ましい抗原結合活性としてpH5.5〜pH6.5の間の抗原結合活性を挙げることができ、より好ましい抗原結合活性としてpH5.8またはpH5.5における抗原結合活性を挙げることができる。
In the screening method of the present invention, the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0 is not particularly limited as long as it is the antigen-binding activity between pH 6.7 and pH 10.0, but as a preferable antigen-binding activity, The antigen-binding activity between pH 7.0 and pH 8.0 can be mentioned, and the antigen-binding activity at pH 7.4 can be mentioned as a more preferable antigen-binding activity. The antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5 is not particularly limited as long as it is an antigen-binding activity between pH 4.0 and pH 6.5, but preferred antigen-binding activity is pH 5.5 to
抗原結合分子の抗原結合活性は当業者に公知の方法により測定することが可能であり、pH以外の条件については当業者が適宜決定することが可能である。抗原結合分子の抗原結合活性は、KD(Dissociation constant:解離定数)、見かけのKD(Apparent dissociation constant:見かけの解離定数)、解離速度であるkd(Dissociation rate:解離速度)、又は見かけのkd(Apparent dissociation:見かけの解離速度)等として評価することが可能である。これらは当業者公知の方法で測定することが可能であり、例えばBiacore (GE healthcare)、スキャッチャードプロット、FACS等を用いることが可能である。 The antigen-binding activity of the antigen-binding molecule can be measured by a method known to those skilled in the art, and conditions other than pH can be appropriately determined by those skilled in the art. The antigen-binding activity of an antigen-binding molecule is KD (Dissociation constant), apparent KD (Apparent dissociation constant), dissociation rate k d (Dissociation rate), or apparent k. It can be evaluated as d (Apparent dissociation: apparent dissociation rate). These can be measured by a method known to those skilled in the art, and for example, Biacore (GE healthcare), Scatchard plot, FACS and the like can be used.
本発明において、pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程は、pH4.0〜pH6.5での抗原結合活性がpH6.7〜pH10.0での抗原結合活性より低い抗原結合分子を選択する工程と同じ意味である。 In the present invention, the step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5 is an antigen at pH 4.0 to pH 6.5. It has the same meaning as the step of selecting an antigen-binding molecule whose binding activity is lower than that of the antigen-binding activity at pH 6.7 to pH 10.0.
pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い限り、pH6.7〜pH10.0での抗原結合活性とpH4.0〜pH6.5での抗原結合活性の差は特に限定されないが、好ましくはpH6.7〜pH10.0における抗原結合活性がpH4.0〜pH6.5での抗原結合活性の2倍以上であり、さらに好ましくは10倍以上であり、より好ましくは40倍以上である。 As long as the antigen-binding activity at pH 6.7 to pH 10.0 is higher than the antigen-binding activity at pH 4.0 to pH 6.5, the antigen-binding activity at pH 6.7 to pH 10.0 and the antigen-binding activity at pH 4.0 to pH 6.5 The difference in the antigen-binding activity of the above is not particularly limited, but the antigen-binding activity at pH 6.7 to pH 10.0 is preferably twice or more, more preferably 10 times or more than the antigen-binding activity at pH 4.0 to pH 6.5. The above is more preferably 40 times or more.
さらに本発明は以下の工程を含む抗原結合分子のスクリーニング方法を提供する。
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) A step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5.
さらに本発明は以下の工程を含む抗原結合分子のスクリーニング方法を提供する。
(a) pH4.0〜pH6.5の条件下で抗原に結合しない抗原結合分子を選択する工程、
(b) (a)で選択された抗原結合分子をpH6.7〜pH10.0の条件下で抗原に結合させる工程、
(c) pH6.7〜pH10.0の条件下で抗原に結合した抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of selecting an antigen-binding molecule that does not bind to an antigen under the conditions of pH 4.0 to pH 6.5,
(b) The step of binding the antigen-binding molecule selected in (a) to the antigen under the conditions of pH 6.7 to pH 10.0,
(c) A step of obtaining an antigen-binding molecule bound to an antigen under the conditions of pH 6.7 to pH 10.0.
さらに本発明は以下の工程を含む抗原結合分子のスクリーニング方法を提供する。
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
(d) 解離した抗原結合分子をコードする遺伝子を増幅する工程、
(e) 溶出された抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
(d) A step of amplifying a gene encoding a dissociated antigen-binding molecule,
(e) A step of obtaining an eluted antigen-binding molecule.
なお、(a)〜(d)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(d)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(d)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (d) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (d) two or more times in the above method. The number of times the steps (a) to (d) are repeated is not particularly limited, but is usually 10 times or less.
さらに本発明は以下の工程を含む抗原結合分子のスクリーニング方法を提供する。
(a) pH4.0〜pH6.5の条件下で抗原に結合しない抗原結合分子を選択する工程、
(b) (a)で選択された抗原結合分子をpH6.7〜pH10.0の条件下で抗原に結合させる工程、
(c) pH6.7〜pH10.0の条件下で抗原に結合した抗原結合分子を取得する工程、
(d) 解離した抗原結合分子をコードする遺伝子を増幅する工程、
(e) 溶出された抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of selecting an antigen-binding molecule that does not bind to an antigen under the conditions of pH 4.0 to pH 6.5,
(b) The step of binding the antigen-binding molecule selected in (a) to the antigen under the conditions of pH 6.7 to pH 10.0,
(c) Step of obtaining an antigen-binding molecule bound to an antigen under the conditions of pH 6.7 to pH 10.0,
(d) A step of amplifying a gene encoding a dissociated antigen-binding molecule,
(e) A step of obtaining an eluted antigen-binding molecule.
なお、(a)〜(d)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(d)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(d)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (d) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (d) two or more times in the above method. The number of times the steps (a) to (d) are repeated is not particularly limited, but is usually 10 times or less.
本発明のスクリーニング方法において、ファージライブラリーなどが用いられる場合には、抗原結合分子をコードする遺伝子を増幅する工程は、ファージを増幅する工程とすることも可能である。 When a phage library or the like is used in the screening method of the present invention, the step of amplifying the gene encoding the antigen-binding molecule can also be a step of amplifying the phage.
本発明の方法において抗原と抗原結合分子の結合は如何なる状態で行われてもよく、特に限定されない。例えば、固定化された抗原結合分子に抗原を接触させることにより抗原結合分子と抗原を結合させてもよいし、固定化された抗原に抗原結合分子を接触させることにより抗原結合分子と抗原を結合させてもよい。又、溶液中で抗原結合分子と抗原を接触させることにより抗原結合分子と抗原を結合させてもよい。 In the method of the present invention, the binding between the antigen and the antigen-binding molecule may be carried out in any state, and is not particularly limited. For example, the antigen-binding molecule may be bound to the antigen by contacting the immobilized antigen-binding molecule with the antigen, or the antigen-binding molecule and the antigen may be bound to each other by contacting the immobilized antigen with the antigen-binding molecule. You may let me. Alternatively, the antigen-binding molecule may be bound to the antigen by contacting the antigen-binding molecule with the antigen in the solution.
さらに本発明は以下の工程を含む抗原結合分子の第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子のスクリーニング方法を提供する。
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, which comprises the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) A step of obtaining an eluted antigen-binding molecule.
さらに本発明は以下の工程を含む抗原結合分子の第一のpHでの結合活性が第二のpHでの結合活性よりも低い抗原結合分子のスクリーニング方法を提供する。
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を通過させる工程、
(b) (a)の工程でカラムに結合せずに溶出した抗原結合分子を回収する工程、
(c) (b)で回収された抗原結合分子を第二のpH条件下でカラムに結合させる工程、
(d) (c)の工程においてカラムに結合した抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule whose binding activity at a first pH is lower than that at a second pH, which comprises the following steps.
(a) A step of passing an antigen-binding molecule through a column on which an antigen is immobilized under the first pH condition,
(b) The step of recovering the antigen-binding molecule eluted without binding to the column in the step (a),
(c) The step of binding the antigen-binding molecule recovered in (b) to the column under the second pH condition,
(d) The step of obtaining the antigen-binding molecule bound to the column in the step (c).
さらに本発明は以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子のスクリーニング方法を提供する。
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, including the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) A step of obtaining an eluted antigen-binding molecule.
なお、(a)〜(c)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(c)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(c)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (c) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (c) two or more times in the above method. The number of times the steps (a) to (c) are repeated is not particularly limited, but is usually 10 times or less.
本発明において、第一のpHと第二のpHはそれぞれが同一のpHでない限り、如何なるpHでもよい。好ましい第一のpHと第二のpHの組み合わせの例として、第一のpHがpH6.7〜10.0の間のpHであり、第二のpHがpH4.0〜pH6.5の間のpHである組み合わせを挙げることができ、より好ましい組み合わせの例としては、第一のpHがpH7.0〜pH8.0の間のpHであり、第二のpHがpH5.5〜pH6.5の間のpHである組み合わせを挙げることができ、さらに好ましい組み合わせの例としては、第一のpHがpH7.4であり、第二のpHがpH5.8またはpH5.5である組み合わせを挙げることができる。 In the present invention, the first pH and the second pH may be any pH as long as they are not the same pH. As an example of a preferred combination of a first pH and a second pH, the first pH is between pH 6.7 and 10.0 and the second pH is between pH 4.0 and pH 6.5. Certain combinations can be mentioned, examples of more preferred combinations are a first pH between pH 7.0 and pH 8.0 and a second pH between pH 5.5 and pH 6.5. A combination of pH can be mentioned, and examples of more preferred combinations include a combination in which the first pH is pH 7.4 and the second pH is pH 5.8 or pH 5.5.
他の好ましい第一のpHと第二のpHの組み合わせの例として、第一のpHがpH4.0〜6.5の間のpHであり、第二のpHがpH6.7〜pH10.0の間のpHである組み合わせを挙げることができ、より好ましい組み合わせの例としては、第一のpHがpH5.5〜pH6.5の間のpHであり、第二のpHがpH7.0〜pH8.0の間のpHである組み合わせを挙げることができ、さらに好ましい組み合わせの例としては、第一のpHがpH5.8またはpH5.5であり、第二のpHがpH7.4である組み合わせを挙げることができる。 As an example of another preferred combination of a first pH and a second pH, the first pH is between pH 4.0 and 6.5 and the second pH is between pH 6.7 and pH 10.0. Combinations that are pH can be mentioned, with examples of more preferred combinations having a first pH between pH 5.5 and pH 6.5 and a second pH between pH 7.0 and pH 8.0. Combinations with pHs in between can be mentioned, and more preferred combinations include combinations with a first pH of pH 5.8 or pH 5.5 and a second pH of pH 7.4. it can.
本発明の方法によりスクリーニングされる抗原結合分子は如何なる抗原結合分子でもよく、例えば上述の抗原結合分子を本発明のスクリーニングに用いることが可能である。例えば、天然の配列を有する抗原結合分子をスクリーニングしてもよいし、アミノ酸配列が置換された抗原結合分子をスクリーニングしてもよい。本発明においてスクリーニングされる抗原結合分子の好ましい例として、例えば、抗原結合分子の少なくとも1つのアミノ酸がヒスチジンで置換された又は少なくとも1つのヒスチジンが挿入された抗原結合分子を挙げることができる。ヒスチジン置換又は挿入が導入される箇所は特に限定されず、如何なる箇所に導入されていてもよい。又、ヒスチジン置換又は挿入は1箇所に導入されてもよいし、2箇所以上の複数の箇所に導入されてもよい。又、本発明においてスクリーニングされる抗原結合分子の好ましい例として、例えば、改変された抗体定常領域を含む抗原結合分子を挙げることができる。 The antigen-binding molecule screened by the method of the present invention may be any antigen-binding molecule, and for example, the above-mentioned antigen-binding molecule can be used for the screening of the present invention. For example, an antigen-binding molecule having a natural sequence may be screened, or an antigen-binding molecule having a substituted amino acid sequence may be screened. Preferred examples of the antigen-binding molecule screened in the present invention include, for example, an antigen-binding molecule in which at least one amino acid of the antigen-binding molecule is replaced with histidine or at least one histidine is inserted. The place where histidine substitution or insertion is introduced is not particularly limited, and may be introduced at any place. Further, the histidine substitution or insertion may be introduced at one place, or may be introduced at a plurality of places of two or more places. Further, as a preferable example of the antigen-binding molecule screened in the present invention, for example, an antigen-binding molecule containing a modified antibody constant region can be mentioned.
本発明の方法によりスクリーニングされる抗原結合分子は、例えば、ヒスチジンスキャンなどの方法により、異なる箇所にヒスチジン置換又は挿入が導入された複数の異なる抗原結合分子であってもよい。 The antigen-binding molecule screened by the method of the present invention may be a plurality of different antigen-binding molecules in which histidine substitution or insertion has been introduced at different locations by, for example, a method such as a histidine scan.
従って、本発明のスクリーニング方法は、抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換する又は少なくとも1つのヒスチジンを挿入する工程をさらに含んでもよい。 Therefore, the screening method of the present invention may further include the step of substituting at least one amino acid of the antigen-binding molecule with histidine or inserting at least one histidine.
なお、本発明のスクリーニング方法はヒスチジンの代わりに非天然アミノ酸を用いてもよい。従って、上述のヒスチジンを非天然アミノ酸と置き換えて本発明を理解することも可能である。 The screening method of the present invention may use an unnatural amino acid instead of histidine. Therefore, it is also possible to understand the present invention by replacing the above-mentioned histidine with an unnatural amino acid.
又、本発明のスクリーニング方法は、抗体定常領域のアミノ酸を改変する工程をさらに含んでもよい。 Further, the screening method of the present invention may further include a step of modifying the amino acid in the antibody constant region.
本発明のスクリーニング方法でスクリーニングされる抗原結合物質はどのように調製されてもよく、例えば、あらかじめ存在している抗体、あらかじめ存在しているライブラリー(ファージライブラリー等)、動物への免疫から得られたハイブリドーマや免疫動物からのB細胞から作製された抗体又はライブラリー、これらの抗体やライブラリーにヒスチジンや非天然アミノ酸変異を導入した抗体又はライブラリー(ヒスチジン又は非天然アミノ酸の含有率を高くしたライブラリーや特定箇所にヒスチジン又は非天然アミノ酸変異を導入したライブラリー等)などを用いることが可能である。 The antigen-binding substance screened by the screening method of the present invention may be prepared in any manner, for example, from pre-existing antibodies, pre-existing libraries (phage library, etc.), immunity to animals, etc. Antibodies or libraries prepared from B cells from the obtained hybridoma or immune animals, antibodies or libraries in which histidine or unnatural amino acid mutations have been introduced into these antibodies or libraries (content of histidine or unnatural amino acids). It is possible to use an elevated library or a library in which histidine or an unnatural amino acid mutation is introduced at a specific site).
本発明のスクリーニング方法により複数回抗原に結合し血漿中滞留性が優れた抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、血漿中滞留性に優れた抗原結合分子を得る為のスクリーニング方法として利用することができる。 According to the screening method of the present invention, it is possible to obtain an antigen-binding molecule that binds to an antigen a plurality of times and has excellent plasma retention. Therefore, the screening method of the present invention can be used as a screening method for obtaining an antigen-binding molecule having excellent plasma retention.
又、本発明のスクリーニング方法により、ヒト、マウス、サルなどの動物に投与した際に、抗原に2回以上結合することが可能である抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、抗原に2回以上結合することができる抗原結合分子を得る為のスクリーニング方法として利用することができる。 Further, according to the screening method of the present invention, it is possible to obtain an antigen-binding molecule capable of binding to an antigen more than once when administered to animals such as humans, mice and monkeys. Therefore, the screening method of the present invention can be used as a screening method for obtaining an antigen-binding molecule capable of binding to an antigen more than once.
さらに、本発明のスクリーニング方法により、ヒト、マウス、サルなどの動物に投与した際に、抗原結合分子の抗原結合部位の数より多い数の抗原に結合することが可能である抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、抗原結合分子の抗原結合部位の数よりも多い数の抗原に結合することが可能である抗原結合分子を得る為のスクリーニング方法として利用することができる。例えば、抗体が中和抗体の場合には、抗原結合分子の抗原結合部位の数よりも多い数の抗原を中和することが可能である抗原結合分子を得る為のスクリーニング方法として利用することができる。 Furthermore, according to the screening method of the present invention, an antigen-binding molecule capable of binding to a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule when administered to animals such as humans, mice, and monkeys is obtained. It is possible. Therefore, the screening method of the present invention can be used as a screening method for obtaining an antigen-binding molecule capable of binding to a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule. For example, when the antibody is a neutralizing antibody, it can be used as a screening method for obtaining an antigen-binding molecule capable of neutralizing a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule. it can.
さらに、本発明のスクリーニング方法により、ヒト、マウス、サルなどの動物に投与した際に、細胞外で結合した抗原を細胞内で解離することが可能である抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、細胞外で結合した抗原を細胞内で解離する抗原結合分子を得る為のスクリーニング方法として利用することができる。 Furthermore, according to the screening method of the present invention, it is possible to obtain an antigen-binding molecule capable of intracellularly dissociating an antigen bound extracellularly when administered to an animal such as a human, mouse, or monkey. .. Therefore, the screening method of the present invention can be used as a screening method for obtaining an antigen-binding molecule that dissociates an extracellularly bound antigen into the cell.
さらに本発明のスクリーニング方法により、ヒト、マウス、サルなどの動物に投与した際に、抗原と結合した状態で細胞内に取り込まれ、抗原と結合していない状態で細胞外に放出される抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、抗原と結合した状態で細胞内に取り込まれ、抗原と結合していない状態で細胞外に放出される抗原結合分子を得る為のスクリーニング方法として利用することができる。 Furthermore, according to the screening method of the present invention, when administered to animals such as humans, mice, and monkeys, antigen binding is taken up into cells in a state of being bound to an antigen and released extracellularly in a state of not binding to an antigen. It is possible to obtain the molecule. Therefore, the screening method of the present invention can be used as a screening method for obtaining an antigen-binding molecule that is taken up into cells in a state of being bound to an antigen and released extracellularly in a state of not binding to an antigen. ..
さらに、本発明のスクリーニング方法により、ヒト、マウス、サルなどの動物に投与した際に、抗原を血漿中から速く消失させることができる抗原結合分子を得ることが可能である。従って、本発明のスクリーニング方法は、血漿中抗原消失能が増加した(高い)抗原結合分子を得る為のスクリーニング方法として利用することができる。 Furthermore, according to the screening method of the present invention, it is possible to obtain an antigen-binding molecule capable of rapidly eliminating an antigen from plasma when administered to animals such as humans, mice and monkeys. Therefore, the screening method of the present invention can be used as a screening method for obtaining a (high) antigen-binding molecule having an increased plasma antigen-eliminating ability.
又、これらの抗原結合分子は、患者への投与量や投与頻度を減らすことが可能であり、結果として総投与量を減らすことが可能となる為、医薬品として特に優れていると考えられる。従って、本発明のスクリーニング方法は、医薬組成物として用いる為の抗原結合分子のスクリーニング方法として利用することが可能である。 In addition, these antigen-binding molecules are considered to be particularly excellent as pharmaceuticals because they can reduce the dose and frequency of administration to patients, and as a result, the total dose can be reduced. Therefore, the screening method of the present invention can be used as a screening method for antigen-binding molecules for use as a pharmaceutical composition.
さらに、本発明は元のライブラリーと比較してヒスチジンを含む割合を上昇させたライブラリーを提供する。ライブラリー中に含まれる抗原結合分子が有するヒスチジンの割合が高くなっているライブラリーは上述のスクリーニング方法や後述の製造方法に用いることが可能である。 In addition, the present invention provides a library with an increased proportion of histidine as compared to the original library. A library in which the proportion of histidine contained in the antigen-binding molecule contained in the library is high can be used in the above-mentioned screening method and the later-described production method.
ヒスチジンを含む割合を高めたライブラリーの作製方法は、当業者に公知の方法を用いることにより作製することが可能であり、例えば以下の方法が挙げられる。ライブラリー作製のための核酸を合成する際に、トリヌクレオチド法(J Mol Biol. 2008 Feb 29;376(4):1182-200.)により、20種類のアミノ酸をコードする20種類の3塩基コドン(トリヌクレオチド)を等しい確率で含有させることによって、ライブラリー化した部位に20種類のアミノ酸が等しい確率で含有させることが可能である。このとき20種類のうちヒスチジンをコードするトリヌクレオチドの割合を他のアミノ酸よりも高くすることによって、ライブラリー化した部位にヒスチジンが出現する可能性を高めることが可能である。 A method for producing a library having an increased proportion of histidine can be produced by using a method known to those skilled in the art, and examples thereof include the following methods. When synthesizing nucleic acids for library production, 20 types of 3-base codons encoding 20 types of amino acids were used by the trinucleotide method (J Mol Biol. 2008 Feb 29; 376 (4): 1182-200.). By containing (trinucleotide) with equal probability, it is possible to contain 20 kinds of amino acids in the library site with equal probability. At this time, by increasing the proportion of the trinucleotide encoding histidine among the 20 types higher than that of other amino acids, it is possible to increase the possibility that histidine appears at the site of library formation.
<抗原結合分子製造方法>
本発明は抗原結合分子のエンドソーム内でのpHにおける抗原結合活性が血漿中でのpHにおける抗原結合活性よりも低い抗原結合分子の製造方法を提供する。又、本発明は血漿中滞留性に優れた抗原結合分子の製造方法を提供する。さらに、本発明は医薬組成物として用いる際に特に有用である抗原結合分子の製造方法を提供する。
<Method for producing antigen-binding molecule>
The present invention provides a method for producing an antigen-binding molecule whose antigen-binding activity at pH in endosome is lower than that at pH in plasma. The present invention also provides a method for producing an antigen-binding molecule having excellent plasma retention. Furthermore, the present invention provides a method for producing an antigen-binding molecule, which is particularly useful when used as a pharmaceutical composition.
具体的には、本発明は以下の工程を含む抗原結合分子の製造方法を提供する。
(a) pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b) pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c) pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程、
(d) (c)で選択された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Specifically, the present invention provides a method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule selected in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
さらに本発明は以下の工程を含む抗原結合分子の製造方法を提供する。
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
さらに本発明は以下の工程を含む抗原結合分子の製造方法を提供する。
(a) pH4.0〜pH6.5の条件下で抗原に結合しない抗原結合分子を選択する工程、
(b) (a)で選択された抗原結合分子をpH6.7〜pH10.0の条件下で抗原に結合させる工程、
(c) pH6.7〜pH10.0の条件下で抗原に結合した抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of selecting an antigen-binding molecule that does not bind to an antigen under the conditions of pH 4.0 to pH 6.5,
(b) The step of binding the antigen-binding molecule selected in (a) to the antigen under the conditions of pH 6.7 to pH 10.0,
(c) Step of obtaining an antigen-binding molecule bound to an antigen under the conditions of pH 6.7 to pH 10.0,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
さらに本発明は以下の工程を含む抗原結合分子の製造方法を提供する。
(a) pH6.7〜10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
(d) 解離した抗原結合分子をコードする遺伝子を増幅する工程、
(e) 溶出された抗原結合分子を取得する工程、
(f) (e)で取得された抗原結合分子をコードする遺伝子を得る工程、
(g) (f)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for producing an antigen-binding molecule, which comprises the following steps.
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
(d) A step of amplifying a gene encoding a dissociated antigen-binding molecule,
(e) Step of obtaining the eluted antigen-binding molecule,
(f) The step of obtaining the gene encoding the antigen-binding molecule obtained in (e),
(g) A step of producing an antigen-binding molecule using the gene obtained in (f).
なお、(a)〜(d)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(d)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(d)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (d) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (d) two or more times in the above method. The number of times the steps (a) to (d) are repeated is not particularly limited, but is usually 10 times or less.
さらに本発明は以下の工程を含む、抗原結合分子のスクリーニング方法を提供する。
(a) pH4.0〜pH6.5の条件下で抗原に結合しない抗原結合分子を選択する工程、
(b) (a)で選択された抗原結合分子をpH6.7〜pH10.0の条件下で抗原に結合させる工程、
(c) pH6.7〜pH10.0の条件下で抗原に結合した抗原結合分子を取得する工程、
(d) 解離した抗原結合分子をコードする遺伝子を増幅する工程、
(e) 溶出された抗原結合分子を取得する工程、
(f) (e)で取得された抗原結合分子をコードする遺伝子を得る工程、
(g) (f)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for screening an antigen-binding molecule, which comprises the following steps.
(a) Step of selecting an antigen-binding molecule that does not bind to an antigen under the conditions of pH 4.0 to pH 6.5,
(b) The step of binding the antigen-binding molecule selected in (a) to the antigen under the conditions of pH 6.7 to pH 10.0,
(c) Step of obtaining an antigen-binding molecule bound to an antigen under the conditions of pH 6.7 to pH 10.0,
(d) A step of amplifying a gene encoding a dissociated antigen-binding molecule,
(e) Step of obtaining the eluted antigen-binding molecule,
(f) The step of obtaining the gene encoding the antigen-binding molecule obtained in (e),
(g) A step of producing an antigen-binding molecule using the gene obtained in (f).
なお、(a)〜(d)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(d)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(d)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (d) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (d) two or more times in the above method. The number of times the steps (a) to (d) are repeated is not particularly limited, but is usually 10 times or less.
さらに、本発明は以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子の製造方法を提供する。
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for producing an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, including the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) Step of obtaining the eluted antigen-binding molecule,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
さらに、本発明は以下の工程を含む第一のpHでの結合活性が第二のpHでの結合活性よりも高い抗原結合分子の製造方法を提供する。
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程、
(e) (d)で取得された抗原結合分子をコードする遺伝子を得る工程、
(f) (e)で得られた遺伝子を用いて抗原結合分子を製造する工程。
Furthermore, the present invention provides a method for producing an antigen-binding molecule whose binding activity at a first pH is higher than that at a second pH, including the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) Step of obtaining the eluted antigen-binding molecule,
(e) The step of obtaining the gene encoding the antigen-binding molecule obtained in (d),
(f) A step of producing an antigen-binding molecule using the gene obtained in (e).
なお、(a)〜(c)の工程は2回以上繰り返されてもよい。従って、本発明は上述の方法において、(a)〜(c)の工程を2回以上繰り返す工程をさらに含む方法を提供する。(a)〜(c)の工程が繰り返される回数は特に限定されないが、通常10回以内である。 The steps (a) to (c) may be repeated twice or more. Therefore, the present invention provides a method further including the step of repeating the steps (a) to (c) two or more times in the above method. The number of times the steps (a) to (c) are repeated is not particularly limited, but is usually 10 times or less.
本発明の製造方法において、ファージライブラリーなどが用いられる場合には、抗原結合分子をコードする遺伝子を増幅する工程は、ファージを増幅する工程とすることも可能である。 When a phage library or the like is used in the production method of the present invention, the step of amplifying the gene encoding the antigen-binding molecule can also be a step of amplifying the phage.
本発明の製造方法で用いられる抗原結合物質はどのように調製されてもよく、例えば、あらかじめ存在している抗体、あらかじめ存在しているライブラリー(ファージライブラリー等)、動物への免疫から得られたハイブリドーマや免疫動物からのB細胞から作製された抗体又はライブラリー、これらの抗体やライブラリーにヒスチジンや非天然アミノ酸変異を導入した抗体又はライブラリー(ヒスチジン又は非天然アミノ酸の含有率を高くしたライブラリーや特定箇所にヒスチジン又は非天然アミノ酸変異を導入したライブラリー等)などを用いることが可能である。 The antigen-binding substance used in the production method of the present invention may be prepared in any way, and is obtained from, for example, a pre-existing antibody, a pre-existing library (phage library, etc.), or immunization to an animal. Antibodies or libraries prepared from B cells from hybridomas and immune animals, antibodies or libraries in which histidine or unnatural amino acid mutations have been introduced into these antibodies or libraries (high content of histidine or unnatural amino acids). It is possible to use a library or a library in which histidine or an unnatural amino acid mutation is introduced at a specific site).
上述の製造方法において、pH6.7〜pH10.0における抗原結合分子の抗原結合活性はpH6.7〜pH10.0の間の抗原結合活性であれば特に限定されないが、好ましい抗原結合活性として、pH7.0〜pH8.0の間の抗原結合活性を挙げることができ、さらに好ましい抗原結合活性としてpH7.4における抗原結合活性を挙げることができる。又、pH4.0〜pH6.5における抗原結合分子の抗原結合活性はpH4.0〜pH6.5の間の抗原結合活性であれば特に限定されないが、好ましい抗原結合活性としてpH5.5〜pH6.5の間の抗原結合活性を挙げることができ、さらに好ましい抗原結合活性としてpH5.8またはpH5.5における抗原結合活性を挙げることができる。
In the above-mentioned production method, the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0 is not particularly limited as long as it is the antigen-binding activity between pH 6.7 and pH 10.0, but
抗原結合分子の抗原結合活性は当業者に公知の方法により測定することが可能であり、pH以外の条件については当業者が適宜決定することが可能である。 The antigen-binding activity of the antigen-binding molecule can be measured by a method known to those skilled in the art, and conditions other than pH can be appropriately determined by those skilled in the art.
pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程は、pH4.0〜pH6.5での抗原結合活性がpH6.7〜pH10.0での抗原結合活性より低い抗原結合分子を選択する工程と同じ意味である。
In the step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5, the antigen-binding activity at pH 4.0 to pH 6.5 is
pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い限り、pH6.7〜pH10.0での抗原結合活性とpH4.0〜pH6.5での抗原結合活性の差は特に限定されないが、好ましくはpH6.7〜pH10.0における抗原結合活性がpH4.0〜pH6.5での抗原結合活性の2倍以上であり、さらに好ましくは10倍以上であり、より好ましくは40倍以上である。 As long as the antigen-binding activity at pH 6.7 to pH 10.0 is higher than the antigen-binding activity at pH 4.0 to pH 6.5, the antigen-binding activity at pH 6.7 to pH 10.0 and the antigen-binding activity at pH 4.0 to pH 6.5 The difference in the antigen-binding activity of the above is not particularly limited, but the antigen-binding activity at pH 6.7 to pH 10.0 is preferably twice or more, more preferably 10 times or more than the antigen-binding activity at pH 4.0 to pH 6.5. The above is more preferably 40 times or more.
上述の製造方法において抗原と抗原結合分子の結合は如何なる状態で行われてもよく、特に限定されない。例えば、固定化された抗原結合分子に抗原を接触させることにより抗原結合分子と抗原を結合させてもよいし、固定化された抗原に抗原結合分子を接触させることにより抗原結合分子と抗原を結合させてもよい。又、溶液中で抗原結合分子と抗原を接触させることにより抗原結合分子と抗原を結合させてもよい。 In the above-mentioned production method, the binding between the antigen and the antigen-binding molecule may be carried out in any state, and is not particularly limited. For example, the antigen-binding molecule may be bound to the antigen by contacting the immobilized antigen-binding molecule with the antigen, or the antigen-binding molecule and the antigen may be bound to each other by contacting the immobilized antigen with the antigen-binding molecule. You may let me. Alternatively, the antigen-binding molecule may be bound to the antigen by contacting the antigen-binding molecule with the antigen in the solution.
上述の製造方法において、第一のpHと第二のpHはそれぞれが同一のpHでない限り、如何なるpHでもよい。好ましい第一のpHと第二のpHの組み合わせの例として、第一のpHがpH6.7〜10.0の間のpHであり、第二のpHがpH4.0〜pH6.5の間のpHである組み合わせを挙げることができ、より好ましい組み合わせの例としては、第一のpHがpH7.0〜pH8.0の間のpHであり、第二のpHがpH5.5〜pH6.5の間のpHである組み合わせを挙げることができ、さらに好ましい組み合わせの例として第一のpHがpH7.4であり、第二のpHがpH5.8またはpH5.5である組み合わせを挙げることができる。 In the above-mentioned production method, the first pH and the second pH may be any pH as long as they are not the same pH. As an example of a preferred combination of a first pH and a second pH, the first pH is between pH 6.7 and 10.0 and the second pH is between pH 4.0 and pH 6.5. Certain combinations can be mentioned, examples of more preferred combinations are a first pH between pH 7.0 and pH 8.0 and a second pH between pH 5.5 and pH 6.5. A combination that is pH can be mentioned, and as an example of a more preferable combination, a combination in which the first pH is pH 7.4 and the second pH is pH 5.8 or pH 5.5 can be mentioned.
他の好ましい第一のpHと第二のpHの組み合わせの例として、第一のpHがpH4.0〜pH6.5の間のpHであり、第二のpHがpH6.7〜pH10.0の間のpHである組み合わせを挙げることができ、より好ましい組み合わせの例としては、第一のpHがpH5.5〜pH6.5の間のpHであり、第二のpHがpH7.0〜pH8.0の間のpHである組み合わせを挙げることができ、さらに好ましい組み合わせの例として第一のpHがpH5.8またはpH5.5であり、第二のpHがpH7.4である組み合わせを挙げることができる。
As an example of another preferred combination of a first pH and a second pH, the first pH is between pH 4.0 and pH 6.5 and the second pH is between pH 6.7 and pH 10.0. Examples of more preferred combinations are those in which the first pH is between pH 5.5 and pH 6.5 and the second pH is between pH 7.0 and
上述の製造方法により製造される抗原結合分子は如何なる抗原結合分子でもよいが、例えば、抗原結合分子の少なくとも1つのアミノ酸がヒスチジンで置換された又は少なくとも1つのヒスチジンが挿入された抗原結合分子を好ましい例として挙げることができる。そのようなヒスチジン変異が導入される箇所は特に限定されず、如何なる箇所に導入されていてもよい。又、ヒスチジン変異は1箇所に導入されてもよいし、2箇所以上の複数の箇所に導入されてもよい。 The antigen-binding molecule produced by the above-mentioned production method may be any antigen-binding molecule, and for example, an antigen-binding molecule in which at least one amino acid of the antigen-binding molecule is replaced with histidine or at least one histidine is inserted is preferable. It can be given as an example. The place where such a histidine mutation is introduced is not particularly limited, and may be introduced at any place. Further, the histidine mutation may be introduced at one site, or may be introduced at a plurality of sites of two or more sites.
従って、本発明の製造方法においては、抗原結合分子の少なくとも1つのアミノ酸をヒスチジンに置換又は挿入する工程をさらに含んでもよい。 Therefore, the production method of the present invention may further include the step of substituting or inserting at least one amino acid of the antigen-binding molecule with histidine.
なお、本発明の製造方法においてはヒスチジンの代わりに非天然アミノ酸を用いてもよい。従って、上述のヒスチジンを非天然アミノ酸と置き換えて本発明を理解することも可能である。 In the production method of the present invention, an unnatural amino acid may be used instead of histidine. Therefore, it is also possible to understand the present invention by replacing the above-mentioned histidine with an unnatural amino acid.
又、上述の製造方法により製造される抗原結合分子の他の態様として、例えば、改変された抗体定常領域を含む抗原結合分子を挙げることができる、従って、本発明の製造方法においては、抗体定常領域中のアミノ酸を改変する工程をさらに含んでもよい。 Further, as another embodiment of the antigen-binding molecule produced by the above-mentioned production method, for example, an antigen-binding molecule containing a modified antibody constant region can be mentioned. Therefore, in the production method of the present invention, the antibody constant can be mentioned. It may further include the step of modifying the amino acid in the region.
本発明の製造方法により製造される抗原結合分子は血漿中滞留性が優れた抗原結合分子である。従って、本発明の製造方法は、血漿中滞留性に優れた抗原結合分子の製造方法として利用することができる。 The antigen-binding molecule produced by the production method of the present invention is an antigen-binding molecule having excellent plasma retention. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule having excellent plasma retention.
又、製造方法により製造される抗原結合分子は、ヒト、マウス、サルなどの動物に投与した際に、抗原に2回以上結合することが可能であると考えられる。従って、本発明の製造方法は、抗原に2回以上結合することができる抗原結合分子の製造方法として利用することができる。 Further, it is considered that the antigen-binding molecule produced by the production method can bind to the antigen more than once when administered to animals such as humans, mice and monkeys. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule capable of binding to an antigen more than once.
さらに、本発明の製造方法により製造される抗原結合分子は、ヒト、マウス、サルなどの動物に投与した際に、抗原結合分子の抗原結合部位の数より多い数の抗原に結合することが可能であると考えられる。従って、本発明の製造方法は、抗原結合分子の抗原結合部位の数よりも多い数の抗原に結合することが可能である抗原結合分子の製造方法として利用することができる。 Furthermore, the antigen-binding molecule produced by the production method of the present invention can bind to a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule when administered to animals such as humans, mice, and monkeys. Is considered to be. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule capable of binding to a larger number of antigens than the number of antigen-binding sites of the antigen-binding molecule.
さらに、本発明の製造方法により製造される抗原結合分子は、ヒト、マウス、サルなどの動物に投与した際に、細胞外で抗原結合分子に結合した抗原を細胞内で抗原結合分子から解離させることが可能であると考えられる。従って、本発明の製造方法は、細胞外で結合した抗原を細胞内で解離することが可能である抗原結合分子の製造方法として利用することができる。 Furthermore, the antigen-binding molecule produced by the production method of the present invention dissociates the antigen bound to the antigen-binding molecule extracellularly from the antigen-binding molecule intracellularly when administered to animals such as humans, mice, and monkeys. Is considered possible. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule capable of intracellularly dissociating an antigen bound extracellularly.
さらに、本発明の製造方法により製造される抗原結合分子は、ヒト、マウス、サルなどの動物に投与した際に、抗原と結合した状態で細胞内に取り込まれた抗原結合分子を、抗原と結合していない状態で細胞外に放出させることが可能であると考えられる。従って、本発明の製造方法は、抗原と結合した状態で細胞内に取り込まれ、抗原と結合していない状態で細胞外に放出される抗原結合分子の製造方法として利用することができる。 Further, the antigen-binding molecule produced by the production method of the present invention binds an antigen-binding molecule incorporated into cells in a state of being bound to an antigen when administered to animals such as humans, mice, and monkeys. It is considered that it is possible to release it extracellularly in the untreated state. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule that is taken up into cells in a state of being bound to an antigen and released extracellularly in a state of not binding to an antigen.
さらに、本発明の製造方法により製造される抗原結合分子は、ヒト、マウス、サルなどの動物に投与した際に、抗原を血漿中から速く消失させることができると考えられる。従って、本発明の製造方法は、血漿中抗原消失能が増加した(高い)抗原結合分子の製造方法として利用することができる。 Furthermore, it is considered that the antigen-binding molecule produced by the production method of the present invention can rapidly eliminate the antigen from plasma when administered to animals such as humans, mice and monkeys. Therefore, the production method of the present invention can be used as a production method of a (high) antigen-binding molecule having an increased ability to eliminate antigen in plasma.
又、これらの抗原結合分子は、患者への投与回数を減らすことが可能であり、医薬品として特に優れていると考えられる。従って、本発明の製造方法は、医薬組成物として用いる為の抗原結合分子の製造方法として利用することが可能である。 In addition, these antigen-binding molecules can reduce the number of administrations to patients, and are considered to be particularly excellent as pharmaceuticals. Therefore, the production method of the present invention can be used as a production method of an antigen-binding molecule for use as a pharmaceutical composition.
本発明の製造方法において得られた遺伝子は、通常、適当なベクターへ担持(挿入)され、宿主細胞へ導入される。該ベクターとしては、挿入した核酸を安定に保持するものであれば特に制限されず、例えば宿主に大腸菌を用いるのであれば、クローニング用ベクターとしてはpBluescriptベクター(Stratagene社製)などが好ましいが、市販の種々のベクターを利用することができる。本発明の抗原結合分子を生産する目的においてベクターを用いる場合には、特に発現ベクターが有用である。発現ベクターとしては、試験管内、大腸菌内、培養細胞内、生物個体内で抗原結合分子を発現するベクターであれば特に制限されないが、例えば、試験管内発現であればpBESTベクター(プロメガ社製)、大腸菌であればpETベクター(Invitrogen社製)、培養細胞であればpME18S-FL3ベクター(GenBank Accession No. AB009864)、生物個体であればpME18Sベクター(Mol Cell Biol. 8:466-472(1988))などが好ましい。ベクターへの本発明のDNAの挿入は、常法により、例えば、制限酵素サイトを用いたリガーゼ反応により行うことができる(Current protocols in Molecular Biology edit. Ausubel et al. (1987) Publish. John Wiley & Sons.Section 11.4-11.11)。 The gene obtained in the production method of the present invention is usually carried (inserted) into an appropriate vector and introduced into a host cell. The vector is not particularly limited as long as it stably holds the inserted nucleic acid. For example, when Escherichia coli is used as the host, a pBluescript vector (manufactured by Stratagene) is preferable as the cloning vector, but it is commercially available. Various vectors of the above can be used. When a vector is used for the purpose of producing the antigen-binding molecule of the present invention, an expression vector is particularly useful. The expression vector is not particularly limited as long as it is a vector that expresses an antigen-binding molecule in vitro, in Escherichia coli, in cultured cells, or in an individual organism. For example, in the case of in vitro expression, pBEST vector (manufactured by Promega), For Escherichia coli, pET vector (manufactured by Invitrogen), for cultured cells, pME18S-FL3 vector (GenBank Accession No. AB009864), for individual organisms, pME18S vector (Mol Cell Biol. 8: 466-472 (1988)) Etc. are preferable. Insertion of the DNA of the present invention into a vector can be carried out by a conventional method, for example, by a ligase reaction using a restriction enzyme site (Current protocols in Molecular Biology edit. Ausubel et al. (1987) Publish. John Wiley & Sons. Section 11.4-11.11).
上記宿主細胞としては特に制限はなく、目的に応じて種々の宿主細胞が用いられる。抗原結合分子を発現させるための細胞としては、例えば、細菌細胞(例:ストレプトコッカス、スタフィロコッカス、大腸菌、ストレプトミセス、枯草菌)、真菌細胞(例:酵母、アスペルギルス)、昆虫細胞(例:ドロソフィラS2、スポドプテラSF9)、動物細胞(例:CHO、COS、HeLa、C127、3T3、BHK、HEK293、Bowes メラノーマ細胞)および植物細胞を例示することができる。宿主細胞へのベクター導入は、例えば、リン酸カルシウム沈殿法、電気パルス穿孔法(Current protocols in Molecular Biology edit. Ausubel et al. (1987) Publish. John Wiley & Sons.Section 9.1-9.9)、リポフェクション法、マイクロインジェクション法などの公知の方法で行うことが可能である。 The host cell is not particularly limited, and various host cells are used depending on the purpose. Examples of cells for expressing an antigen-binding molecule include bacterial cells (eg, streptococcus, staphylococcus, Escherichia coli, streptomyces, bacillus), fungal cells (eg, yeast, aspergillus), and insect cells (eg, drosophila). S2, Spodoptera SF9), animal cells (eg, CHO, COS, HeLa, C127, 3T3, BHK, HEK293, Bowes melanoma cells) and plant cells can be exemplified. Vector introduction into host cells includes, for example, calcium phosphate precipitation method, electric pulse perforation method (Current protocols in Molecular Biology edit. Ausubel et al. (1987) Publish. John Wiley & Sons. Section 9.1-9.9), lipofection method, micro. It can be performed by a known method such as an injection method.
宿主細胞の培養は、公知の方法に従って行うことができる。例えば、動物細胞を宿主とした場合、培養液として、例えば、DMEM、MEM、RPMI1640、IMDMを使用することができる。その際、FBS、牛胎児血清(FCS)等の血清補液を併用しても、無血清培養により細胞を培養してもよい。培養時のpHは、約6〜8とするのが好ましい。培養は、通常、約30〜40℃で約15〜200時間行い、必要に応じて培地の交換、通気、攪拌を加える。 The host cells can be cultured according to a known method. For example, when animal cells are used as a host, for example, DMEM, MEM, RPMI1640, and IMDM can be used as the culture medium. At that time, serum replacement fluids such as FBS and fetal bovine serum (FCS) may be used in combination, or cells may be cultured by serum-free culture. The pH at the time of culturing is preferably about 6 to 8. Culturing is usually carried out at about 30-40 ° C. for about 15-200 hours, with medium replacement, aeration and stirring as needed.
宿主細胞において発現した抗原結合分子を小胞体の内腔に、細胞周辺腔に、または細胞外の環境に分泌させるために、適当な分泌シグナルを目的のポリペプチドに組み込むことができる。これらのシグナルは目的の抗原結合分子に対して内因性であっても、異種シグナルであってもよい。 Appropriate secretory signals can be incorporated into the polypeptide of interest in order for the antigen-binding molecule expressed in the host cell to be secreted into the endoplasmic reticulum lumen, the pericellular cavity, or the extracellular environment. These signals may be endogenous or heterologous to the antigen-binding molecule of interest.
一方、in vivoでポリペプチドを産生させる系としては、例えば、動物を使用する産生系や植物を使用する産生系が挙げられる。これらの動物又は植物に目的とするポリヌクレオチドを導入し、動物又は植物の体内でポリペプチドを産生させ、回収する。本発明における「宿主」とは、これらの動物、植物を包含する。 On the other hand, examples of the system for producing a polypeptide in vivo include a production system using an animal and a production system using a plant. The polynucleotide of interest is introduced into these animals or plants to produce and recover the polypeptide in the body of the animal or plant. The "host" in the present invention includes these animals and plants.
動物を使用する場合、哺乳類動物、昆虫を用いる産生系がある。哺乳類動物としては、ヤギ、ブタ、ヒツジ、マウス、ウシ等を用いることができる(Vicki Glaser, SPECTRUM Biotechnology Applications (1993))。また、哺乳類動物を用いる場合、トランスジェニック動物を用いることができる。 When using animals, there are production systems that use mammals and insects. As mammals, goats, pigs, sheep, mice, cows and the like can be used (Vicki Glaser, SPECTRUM Biotechnology Applications (1993)). When mammals are used, transgenic animals can be used.
例えば、本発明の抗原結合分子をコードするポリヌクレオチドを、ヤギβカゼインのような乳汁中に固有に産生されるポリペプチドをコードする遺伝子との融合遺伝子として調製する。次いで、この融合遺伝子を含むポリヌクレオチド断片をヤギの胚へ注入し、この胚を雌のヤギへ移植する。胚を受容したヤギから生まれるトランスジェニックヤギ又はその子孫が産生する乳汁から、目的の抗原結合分子を得ることができる。トランスジェニックヤギから産生される抗原結合分子を含む乳汁量を増加させるために、適宜ホルモンをトランスジェニックヤギに投与してもよい(Ebert et al., Bio/Technology (1994) 12: 699-702)。 For example, the polynucleotide encoding the antigen-binding molecule of the present invention is prepared as a fusion gene with a gene encoding a polypeptide uniquely produced in milk, such as goat β-casein. A polynucleotide fragment containing this fusion gene is then injected into a goat embryo and the embryo is transplanted into a female goat. The antigen-binding molecule of interest can be obtained from the milk produced by a transgenic goat born from a goat that has received an embryo or its offspring. In order to increase the amount of milk containing the antigen-binding molecule produced by the transgenic goat, the hormone may be administered to the transgenic goat as appropriate (Ebert et al., Bio / Technology (1994) 12: 699-702). ..
また、本発明の抗原結合分子を産生させる昆虫としては、例えばカイコを用いることができる。カイコを用いる場合、目的の抗原結合分子をコードするポリヌクレオチドを挿入したバキュロウィルスをカイコに感染させることにより、このカイコの体液から目的の抗原結合分子を得ることができる。 Further, as the insect that produces the antigen-binding molecule of the present invention, for example, silk moth can be used. When the silk moth is used, the target antigen-binding molecule can be obtained from the body fluid of the silk moth by infecting the silk moth with a baculovirus in which a polynucleotide encoding the target antigen-binding molecule is inserted.
さらに、植物を本発明の抗原結合分子産生に使用する場合、例えばタバコを用いることができる。タバコを用いる場合、目的とする抗原結合分子をコードするポリヌクレオチドを植物発現用ベクター、例えばpMON 530に挿入し、このベクターをアグロバクテリウム・ツメファシエンス(Agrobacterium tumefaciens)のようなバクテリアに導入する。このバクテリアをタバコ、例えば、ニコチアナ・タバカム(Nicotiana tabacum)に感染させ、本タバコの葉より所望の抗原結合分子を得ることができる(Ma et al., Eur. J. Immunol. (1994) 24: 131-8)。また、同様のバクテリアをウキクサ(Lemna minor)に感染させ、クローン化した後にウキクサの細胞より所望の抗原結合分子を得ることができる(Cox KM et al. Nat. Biotechnol. 2006 Dec;24(12):1591-1597)。 Furthermore, when plants are used for the production of antigen-binding molecules of the present invention, for example, tobacco can be used. When using tobacco, a polynucleotide encoding the antigen-binding molecule of interest is inserted into a plant expression vector, such as pMON 530, and the vector is introduced into a bacterium such as Agrobacterium tumefaciens. This bacterium can be infected with tobacco, such as Nicotiana tabacum, to obtain the desired antigen-binding molecule from the leaves of this tobacco (Ma et al., Eur. J. Immunol. (1994) 24: 131-8). In addition, similar bacteria can be infected with Lemna minor and cloned to obtain the desired antigen-binding molecule from Duckweed cells (Cox KM et al. Nat. Biotechnol. 2006 Dec; 24 (12)). : 1591-1597).
このようにして得られた抗原結合分子は、宿主細胞内または細胞外(培地、乳汁など)から単離し、実質的に純粋で均一な抗原結合分子として精製することができる。抗原結合分子の分離、精製は、通常のポリペプチドの精製で使用されている分離、精製方法を使用すればよく、何ら限定されるものではない。例えば、クロマトグラフィーカラム、フィルター、限外濾過、塩析、溶媒沈殿、溶媒抽出、蒸留、免疫沈降、SDS-ポリアクリルアミドゲル電気泳動、等電点電気泳動法、透析、再結晶等を適宜選択、組み合わせて抗原結合分子を分離、精製することができる。 The antigen-binding molecule thus obtained can be isolated intracellularly or extracellularly (medium, milk, etc.) and purified as a substantially pure and uniform antigen-binding molecule. Separation and purification of the antigen-binding molecule may be performed by using the separation and purification methods used in the purification of ordinary polypeptides, and is not limited in any way. For example, chromatography column, filter, ultrafiltration, salting out, solvent precipitation, solvent extraction, distillation, immunoprecipitation, SDS-polyacrylamide gel electrophoresis, isoelectric focusing, dialysis, recrystallization, etc. are appropriately selected. The antigen-binding molecule can be separated and purified in combination.
クロマトグラフィーとしては、例えばアフィニティクロマトグラフィー、イオン交換クロマトグラフィー、疎水性クロマトグラフィー、ゲル濾過、逆相クロマトグラフィー、吸着クロマトグラフィー等が挙げられる(Strategies for Protein Purification and Characterization: A Laboratory Course Manual. Ed Daniel R. Marshak et al.(1996) Cold Spring Harbor Laboratory Press)。これらのクロマトグラフィーは、液相クロマトグラフィー、例えばHPLC、FPLC等の液相クロマトグラフィーを用いて行うことができる。アフィニティクロマトグラフィーに用いるカラムとしては、プロテインAカラム、プロテインGカラムが挙げられる。例えば、プロテインAを用いたカラムとして、Hyper D, POROS, Sepharose F. F. (Pharmacia製)等が挙げられる。 Chromatography includes, for example, affinity chromatography, ion exchange chromatography, hydrophobic chromatography, gel filtration, reverse phase chromatography, adsorption chromatography and the like (Strategies for Protein Purification and characterization: A Laboratory Course Manual. Ed Daniel). R. Marshak et al. (1996) Cold Spring Harbor Laboratory Press). These chromatographies can be performed using liquid phase chromatography, for example, liquid phase chromatography such as HPLC or FPLC. Examples of the column used for affinity chromatography include a protein A column and a protein G column. For example, as a column using protein A, Hyper D, POROS, Sepharose F.F. (manufactured by Pharmacia) and the like can be mentioned.
必要に応じ、抗原結合分子の精製前又は精製後に適当なタンパク質修飾酵素を作用させることにより、任意に修飾を加えたり、部分的にペプチドを除去することもできる。タンパク質修飾酵素としては、例えば、トリプシン、キモトリプシン、リシルエンドペプチダーゼ、プロテインキナーゼ、グルコシダーゼなどが用いられる。 If necessary, the peptide can be optionally modified or the peptide can be partially removed by allowing an appropriate protein-modifying enzyme to act before or after purification of the antigen-binding molecule. As the protein modifying enzyme, for example, trypsin, chymotrypsin, lysyl endopeptidase, protein kinase, glucosidase and the like are used.
<抗IL-6受容体抗体>
さらに、本発明は以下の(a)〜(m)のいずれかに記載の抗IL-6受容体抗体を提供する。
(a) 配列番号:1(H53可変領域)のアミノ酸配列において27番目のTyr、31番目のAsp、32番目のAsp、35番目のTrp、51番目のTyr、59番目のAsn、63番目のSer、106番目のMet、108番目のTyrの少なくとも1つがHisに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体、
(b) 配列番号:1(H53可変領域)のアミノ酸配列において27番目のTyr、31番目のAspおよび35番目のTrpがHisに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体(H3pI)、
(c) 配列番号:1(H53可変領域)のアミノ酸配列において27番目のTyr、31番目のAsp、32番目のAsp、35番目のTrp、59番目のAsn、63番目およびSer、108番目のTyrがHisに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体、
(d) 配列番号:1(H53可変領域)のアミノ酸配列において27番目のTyr、31番目のAsp、32番目のAsp、35番目のTrp、59番目のAsn、63番目およびSer、108番目のTyrがHisに置換され、かつ99番目のSerがValに、103番目のThrがIleに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体(H170)、
(e) 配列番号:1(H53可変領域)のアミノ酸配列において31番目のAsp、51番目のTyr、63番目のSer、106番目のMetおよび108番目のTyrがHisに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体、
(f) 配列番号:1(H53可変領域)のアミノ酸配列において31番目のAsp、51番目のTyr、63番目のSer、106番目のMetおよび108番目のTyrがHisに置換され、かつ99番目のSerがPheに、103番目のThrがIleに置換されたアミノ酸配列を有する重鎖可変領域を含む抗体(CLH5)、
(g) 配列番号:2(PF1L可変領域)のアミノ酸配列において、28番目のAsp、32番目のTyr、53番目のGlu、56番目のSer、92番目のAsnの少なくとも1つがHisに置換されたアミノ酸配列を有する軽鎖可変領域を含む抗体、
(h) 配列番号:2(PF1L可変領域)のアミノ酸配列において、28番目のAsp、32番目のTyrおよび53番目のGluがHisに置換されたアミノ酸配列を有する軽鎖可変領域を含む抗体(L73)、
(i) 配列番号:1(H53可変領域)のアミノ酸配列において、32番目のTyrおよび53番目のGluがHisに置換されたアミノ酸配列を有する軽鎖可変領域を含む抗体(L82)、
(j) 配列番号:2(PF1L可変領域)のアミノ酸配列において、32番目のTyr、53番目のGlu、56番目のSerおよび92番目のAsnがHisに置換されたアミノ酸配列を有する軽鎖可変領域を含む抗体(CLL5)、
(k) (b)の重鎖可変領域および(h)の軽鎖可変領域を含む抗体、
(l) (d)の重鎖可変領域および(i)の軽鎖可変領域を含む抗体、
(m) (f)の重鎖可変領域および(h)の軽鎖可変領域を含む抗体。
<Anti-IL-6 receptor antibody>
Furthermore, the present invention provides the anti-IL-6 receptor antibody according to any one of (a) to (m) below.
(a) In the amino acid sequence of SEQ ID NO: 1 (H53 variable region), 27th Tyr, 31st Asp, 32nd Asp, 35th Trp, 51st Tyr, 59th Asn, 63rd Ser , 106th Met, 108th Tyr antibody containing a heavy chain variable region having an amino acid sequence in which at least one is substituted with His,
(b) An antibody (H3pI) containing a heavy chain variable region having an amino acid sequence in which Tyr at position 27, Asp at position 31 and Trp at
(c) Tyr 27th, Asp 31st, Asp 32nd, Trp 35th, Asn 59th, 63rd and Ser, Tyr 108th in the amino acid sequence of SEQ ID NO: 1 (H53 variable region) An antibody containing a heavy chain variable region having an amino acid sequence in which is substituted with His,
(d) In the amino acid sequence of SEQ ID NO: 1 (H53 variable region), 27th Tyr, 31st Asp, 32nd Asp, 35th Trp, 59th Asn, 63rd and Ser, 108th Tyr An antibody (H170) containing a heavy chain variable region having an amino acid sequence in which is substituted with His and Ser at position 99 is substituted with Val and Thr at position 103 is substituted with Ile.
(e) In the amino acid sequence of SEQ ID NO: 1 (H53 variable region), the 31st Asp, the 51st Tyr, the 63rd Ser, the 106th Met and the 108th Tyr have an amino acid sequence in which His is substituted. Antibodies containing heavy chain variable regions,
(f) In the amino acid sequence of SEQ ID NO: 1 (H53 variable region), the 31st Asp, the 51st Tyr, the 63rd Ser, the 106th Met and the 108th Tyr are replaced with His, and the 99th Tyr. An antibody (CLH5) containing a heavy chain variable region having an amino acid sequence in which Ser is replaced with Phe and Thr at position 103 is replaced with Ile.
(g) In the amino acid sequence of SEQ ID NO: 2 (PF1L variable region), at least one of Asp at 28th, Tyr at 32nd, Glu at 53rd, Ser at 56th, and Asn at 92nd was replaced with His. An antibody containing a light chain variable region having an amino acid sequence,
(h) In the amino acid sequence of SEQ ID NO: 2 (PF1L variable region), an antibody (L73) containing a light chain variable region having an amino acid sequence in which Asp at
(i) An antibody (L82) containing a light chain variable region having an amino acid sequence in which Tyr at position 32 and Glu at position 53 are replaced with His in the amino acid sequence of SEQ ID NO: 1 (H53 variable region).
(j) In the amino acid sequence of SEQ ID NO: 2 (PF1L variable region), the light chain variable region having the amino acid sequence in which Tyr at position 32, Glu at position 53, Ser at position 56 and Asn at position 92 are replaced with His. Contains antibodies (CLL5),
(k) Antibodies containing the heavy chain variable region of (b) and the light chain variable region of (h),
(l) Antibodies containing the heavy chain variable region of (d) and the light chain variable region of (i),
(m) An antibody containing the heavy chain variable region of (f) and the light chain variable region of (h).
配列番号:1(H53可変領域)のアミノ酸配列において27番目のTyr、31番目のAsp、32番目のAsp、35番目のTrp、51番目のTyr、59番目のAsn、63番目のSer、106番目のMet、108番目のTyrの少なくとも1つがHisに置換されたアミノ酸配列を有する重鎖可変領域の具体的な例としては、例えば、以下の重鎖可変領域を挙げることができる。
配列番号:3(H3pI)のアミノ酸配列を有する重鎖可変領域
配列番号:4(H170)のアミノ酸配列を有する重鎖可変領域
配列番号:5(CLH5)のアミノ酸配列を有する重鎖可変領域
SEQ ID NO: 1 (H53 variable region) amino acid sequence 27th Tyr, 31st Asp, 32nd Asp, 35th Trp, 51st Tyr, 59th Asn, 63rd Ser, 106th As a specific example of a heavy chain variable region having an amino acid sequence in which at least one of Met and Tyr at position 108 is substituted with His, for example, the following heavy chain variable region can be mentioned.
SEQ ID NO:: heavy chain variable region having an amino acid sequence of 3 (H3pI) SEQ ID NO:: heavy chain variable region having an amino acid sequence of 4 (H170) SEQ ID NO:: heavy chain variable region having an amino acid sequence of 5 (CLH5)
配列番号:2(PF1L可変領域)のアミノ酸配列において、28番目のAsp、32番目のTyr、53番目のGlu、56番目のSer、92番目のAsnの少なくとも1つがHisに置換されたアミノ酸配列を有する軽鎖可変領域の具体的な例としては、例えば、以下の軽鎖可変領域を挙げることができる。
配列番号:6(L73)のアミノ酸配列を有する軽鎖可変領域
配列番号:7(L82)のアミノ酸配列を有する軽鎖可変領域
配列番号:8(CLL5)のアミノ酸配列を有する軽鎖可変領域
In the amino acid sequence of SEQ ID NO: 2 (PF1L variable region), the amino acid sequence in which at least one of 28th Asp, 32nd Tyr, 53rd Glu, 56th Ser, and 92nd Asn is replaced with His is used. Specific examples of the light chain variable region having the light chain include the following light chain variable region.
Light chain variable region having the amino acid sequence of SEQ ID NO: 6 (L73) Light chain variable region having the amino acid sequence of SEQ ID NO: 7 (L82) Light chain variable region having the amino acid sequence of SEQ ID NO: 8 (CLL5)
上述のH3pI、H170、CLH5、L73、L82、およびCLL5の各抗体におけるアミノ酸位置とアミノ酸置換について、以下の表1に示す。アミノ酸位置はKabatナンバリングに基づいて示している。 The amino acid positions and amino acid substitutions in each of the above-mentioned H3pI, H170, CLH5, L73, L82, and CLL5 antibodies are shown in Table 1 below. Amino acid positions are shown based on Kabat numbering.
[表1]
[Table 1]
*H鎖の33番目、および、L鎖の55番目はWTにおいてヒスチジンの配列を有する。 * The 33rd position of the H chain and the 55th position of the L chain have a histidine sequence in WT.
本発明は少なくとも上述の(a)〜(j)のいずれかに記載のアミノ酸置換を含む抗体及び該抗体の製造方法を提供する。従って本発明の抗体には、上述の(a)〜(j)のいずれかに記載のアミノ酸置換に加え、上述の(a)〜(j)に記載のアミノ酸置換以外のアミノ酸置換を含む抗体も含まれる。上述の(a)〜(j)に記載のアミノ酸置換以外のアミノ酸置換としては、例えば、CDR部分のアミノ酸配列の置換、欠失、付加および/または挿入等や、FRのアミノ酸配列の置換、欠失、付加および/または挿入等が挙げられる。 The present invention provides an antibody containing at least the amino acid substitution according to any one of (a) to (j) above, and a method for producing the antibody. Therefore, the antibody of the present invention includes an antibody containing an amino acid substitution other than the amino acid substitutions described in (a) to (j) above, in addition to the amino acid substitution described in any of (a) to (j) above. included. Examples of amino acid substitutions other than the amino acid substitutions described in (a) to (j) above include substitution, deletion, addition and / or insertion of the amino acid sequence of the CDR portion, and substitution and deficiency of the amino acid sequence of FR. Loss, addition and / or insertion, etc. may be mentioned.
さらに本発明は以下の(1)から(28)のいずれかに記載の抗IL-6受容体抗体を提供する。
(1) 配列番号:21(VH1-IgG1)の1番目から119番目までのアミノ酸配列を有する重鎖可変領域(VH1-IgG1可変領域)を含む抗体、
(2) 配列番号:22(VH2-IgG1)の1番目から119番目までのアミノ酸配列を有する重鎖可変領域(VH2-IgG1可変領域)を含む抗体、
(3) 配列番号:23(VH3-IgG1)の1番目から119番目までのアミノ酸配列を有する重鎖可変領域(VH3-IgG1可変領域)を含む抗体、
(4) 配列番号:24(VH4-IgG1)の1番目から119番目までのアミノ酸配列を有する重鎖可変領域(VH4-IgG1可変領域)を含む抗体、
(5) 配列番号:25(VL1-CK)の1番目から107番目までのアミノ酸配列を有する軽鎖可変領域(VL1-CK可変領域)を含む抗体、
(6) 配列番号:26(VL2-CK)の1番目から107番目までのアミノ酸配列を有する軽鎖可変領域(VL2-CK可変領域)を含む抗体、
(7) 配列番号:27(VL3-CK)の1番目から107番目までのアミノ酸配列を有する軽鎖可変領域(VL3-CK可変領域)を含む抗体、
(8) (2)の重鎖可変領域と(6)の軽鎖可変領域を含む抗体(Fv1-IgG1)、
(9) (1)の重鎖可変領域と配列番号:7(L82)に記載のアミノ酸配列を有する軽鎖可変領域を含む抗体(Fv2-IgG1)、
(10) (4)の重鎖可変領域と(5)の軽鎖可変領域を含む抗体(Fv3-IgG1)、
(11) (3)の重鎖可変領域と(7)の軽鎖可変領域を含む抗体(Fv4-IgG1)、
(12) 配列番号:33に記載のアミノ酸配列を有する重鎖を含む抗体(VH3-IgG2ΔGK)、
(13) 配列番号:34に記載のアミノ酸配列を有する重鎖を含む抗体(VH3-M58)、
(14) 配列番号:35に記載のアミノ酸配列を有する重鎖を含む抗体(VH3-M73)、
(15) (12)の重鎖と配列番号:27(VL3-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv4-IgG2ΔGK)、
(16) (13)の重鎖と配列番号:27(VL3-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv4-M58)、
(17) (14)の重鎖と配列番号:27(VL3-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv4-M73)、
(18) 配列番号:36(VH2-M71)のアミノ酸配列を有する重鎖を含む抗体(VH2-M71)、
(19) 配列番号:37(VH2-M73)のアミノ酸配列を有する重鎖を含む抗体(VH2-M73)、
(20) 配列番号:38(VH4-M71)のアミノ酸配列を有する重鎖を含む抗体(VH4-M71)、
(21) 配列番号:39(VH4-M73)のアミノ酸配列を有する重鎖を含む抗体(VH4-M73)、
(22) (18)の重鎖と配列番号:26(VL2-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv1-M71)、
(23) (19)の重鎖と配列番号:26(VL2-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv1-M73)、
(24) (20)の重鎖と配列番号:25(VL1-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv3-M71)、
(25) (21)の重鎖と配列番号:25(VL1-CK)のアミノ酸配列を有する軽鎖を含む抗体(Fv3-M73)、
(26) 配列番号:25(VL1-CK)のアミノ酸配列を有する軽鎖を含む抗体、
(27) 配列番号:26(VL2-CK)のアミノ酸配列を有する軽鎖を含む抗体、
(28) 配列番号:27(VL3-CK)のアミノ酸配列を有する軽鎖を含む抗体。
Furthermore, the present invention provides the anti-IL-6 receptor antibody according to any one of (1) to (28) below.
(1) An antibody containing a heavy chain variable region (VH1-IgG1 variable region) having the
(2) An antibody containing a heavy chain variable region (VH2-IgG1 variable region) having the
(3) An antibody containing a heavy chain variable region (VH3-IgG1 variable region) having the
(4) An antibody containing a heavy chain variable region (VH4-IgG1 variable region) having the
(5) An antibody containing a light chain variable region (VL1-CK variable region) having the
(6) An antibody containing a light chain variable region (VL2-CK variable region) having the
(7) An antibody containing a light chain variable region (VL3-CK variable region) having the
(8) An antibody (Fv1-IgG1) containing the heavy chain variable region of (2) and the light chain variable region of (6),
(9) An antibody (Fv2-IgG1) containing a heavy chain variable region of (1) and a light chain variable region having the amino acid sequence shown in SEQ ID NO: 7 (L82).
(10) An antibody (Fv3-IgG1) containing the heavy chain variable region of (4) and the light chain variable region of (5),
(11) An antibody (Fv4-IgG1) containing the heavy chain variable region of (3) and the light chain variable region of (7),
(12) An antibody (VH3-IgG2ΔGK) containing a heavy chain having the amino acid sequence shown in SEQ ID NO: 33,
(13) An antibody (VH3-M58) containing a heavy chain having the amino acid sequence shown in SEQ ID NO: 34,
(14) Antibody containing a heavy chain having the amino acid sequence set forth in SEQ ID NO: 35 (VH3-M73),
(15) An antibody (Fv4-IgG2ΔGK) containing the heavy chain of (12) and the light chain having the amino acid sequence of SEQ ID NO: 27 (VL3-CK),
(16) An antibody (Fv4-M58) containing the heavy chain of (13) and the light chain having the amino acid sequence of SEQ ID NO: 27 (VL3-CK),
(17) An antibody (Fv4-M73) containing the heavy chain of (14) and the light chain having the amino acid sequence of SEQ ID NO: 27 (VL3-CK),
(18) A heavy chain-containing antibody (VH2-M71) having the amino acid sequence of SEQ ID NO: 36 (VH2-M71),
(19) A heavy chain-containing antibody (VH2-M73) having the amino acid sequence of SEQ ID NO: 37 (VH2-M73),
(20) A heavy chain-containing antibody (VH4-M71) having the amino acid sequence of SEQ ID NO: 38 (VH4-M71),
(21) A heavy chain-containing antibody (VH4-M73) having the amino acid sequence of SEQ ID NO: 39 (VH4-M73),
(22) An antibody (Fv1-M71) containing the heavy chain of (18) and the light chain having the amino acid sequence of SEQ ID NO: 26 (VL2-CK),
(23) An antibody (Fv1-M73) containing the heavy chain of (19) and the light chain having the amino acid sequence of SEQ ID NO: 26 (VL2-CK),
(24) An antibody (Fv3-M71) containing the heavy chain of (20) and the light chain having the amino acid sequence of SEQ ID NO: 25 (VL1-CK),
(25) An antibody (Fv3-M73) containing the heavy chain of (21) and the light chain having the amino acid sequence of SEQ ID NO: 25 (VL1-CK),
(26) An antibody comprising a light chain having the amino acid sequence of SEQ ID NO: 25 (VL1-CK),
(27) An antibody comprising a light chain having the amino acid sequence of SEQ ID NO: 26 (VL2-CK),
(28) An antibody comprising a light chain having the amino acid sequence of SEQ ID NO: 27 (VL3-CK).
さらに本発明は以下の(a)〜(v)いずれかのFRまたはCDRを提供する。
(a) 配列番号:40に記載の重鎖CDR1(VH1,2,3,4)、
(b) 配列番号:41に記載の重鎖CDR2(VH1,2)、
(c) 配列番号:42に記載の重鎖CDR2(VH3)、
(d) 配列番号:43に記載の重鎖CDR2(VH4)、
(e) 配列番号:44に記載の重鎖CDR3(VH1,2)、
(f) 配列番号:45に記載の重鎖CDR3(VH3,4)、
(g) 配列番号:46に記載の重鎖FR1(VH1,2)、
(h) 配列番号:47に記載の重鎖FR1(VH3,4)、
(i) 配列番号:48に記載の重鎖FR2(VH1,2,3,4)
(j) 配列番号:49に記載の重鎖FR3(VH1)、
(k) 配列番号:50に記載の重鎖FR3(VH2)、
(l) 配列番号:51に記載の重鎖FR3(VH3,4)、
(m) 配列番号:52に記載の重鎖FR4(VH1,2,3,4)
(n) 配列番号:53に記載の軽鎖CDR1(VL1,2)、
(o) 配列番号:54に記載の軽鎖CDR1(VL3)、
(p) 配列番号:55に記載の軽鎖CDR2(VL1,VL3)、
(q) 配列番号:56に記載の軽鎖CDR2(VL2)、
(r) 配列番号:57に記載の軽鎖CDR3(VL1,2,3)、
(s) 配列番号:58に記載の軽鎖FR1(VL1,2,3)、
(t) 配列番号:59に記載の軽鎖FR2(VL1,2,3)、
(u) 配列番号:60に記載の軽鎖FR3(VL1,2,3)、
(v) 配列番号:61に記載の軽鎖FR4(VL1,2,3)。
Furthermore, the present invention provides any of the following FRs or CDRs (a) to (v).
(a) Heavy chain CDR1 (VH1,2,3,4), SEQ ID NO: 40.
(b) Heavy chain CDR2 (VH1,2) according to SEQ ID NO: 41,
(c) Heavy chain CDR2 (VH3), SEQ ID NO: 42,
(d) Heavy chain CDR2 (VH4), SEQ ID NO: 43,
(e) Heavy chain CDR3 (VH1,2), SEQ ID NO: 44,
(f) Heavy chain CDR3 (VH3,4), SEQ ID NO: 45,
(g) Heavy chain FR1 (VH1,2), SEQ ID NO: 46,
(h) Heavy chain FR1 (VH3,4), SEQ ID NO: 47,
(i) Heavy chain FR2 (VH1,2,3,4) according to SEQ ID NO: 48.
(j) Heavy chain FR3 (VH1), SEQ ID NO: 49,
(k) Heavy chain FR3 (VH2), SEQ ID NO: 50,
(l) Heavy chain FR3 (VH3,4), SEQ ID NO: 51.
(m) Heavy chain FR4 (VH1,2,3,4) according to SEQ ID NO: 52.
(n) Light chain CDR1 (VL1,2), SEQ ID NO: 53,
(o) Light chain CDR1 (VL3), SEQ ID NO: 54,
(p) Light chain CDR2 (VL1, VL3), SEQ ID NO: 55,
(q) Light chain CDR2 (VL2), SEQ ID NO: 56,
(r) Light chain CDR3 (VL1,2,3), SEQ ID NO: 57,
(s) Light chain FR1 (VL1,2,3), SEQ ID NO: 58,
(t) Light chain FR2 (VL1,2,3), SEQ ID NO: 59,
(u) Light chain FR3 (VL1,2,3), SEQ ID NO: 60,
(v) Light chain FR4 (VL1,2,3) according to SEQ ID NO: 61.
上記(a)〜(v)の各配列を、図25にまとめて示す。また本発明は、上記(a)〜(v)のいずれかのFRまたはCDRを含むポリペプチドを提供する。 The sequences (a) to (v) above are collectively shown in FIG. The present invention also provides a polypeptide containing any of the FRs or CDRs (a) to (v) above.
本発明の抗IL-6受容体抗体には、上述のいずれかに記載のアミノ酸置換を含む抗体の断片やその修飾物も含まれる。例えば、抗体の断片としては、Fab、F(ab')2、Fv又はH鎖とL鎖のFvを適当なリンカーで連結させたシングルチェインFv(scFv)、H鎖単独ドメインやL鎖単独ドメイン(例えば、Nat Biotechnol. 2005 Sep;23(9):1126-36.)、Unibody(WO2007059782 A1)、SMIP(WO2007014278 A2)が挙げられる。また抗体の由来としては、特に限定されないが、ヒト抗体、マウス抗体、ラット抗体、ウサギ抗体などを挙げることができる。又、本発明の抗体はキメラ抗体、ヒト化抗体、完全ヒト化抗体等であってもよい。 The anti-IL-6 receptor antibody of the present invention also includes a fragment of the antibody containing the amino acid substitution described in any of the above and a modified product thereof. For example, antibody fragments include Fab, F (ab') 2, Fv or single chain Fv (scFv) in which H chain and L chain Fv are linked with an appropriate linker, H chain single domain or L chain single domain. (For example, Nat Biotechnol. 2005 Sep; 23 (9): 1126-36.), Unibody (WO2007059782 A1), SMIP (WO2007014278 A2). The origin of the antibody is not particularly limited, and examples thereof include human antibody, mouse antibody, rat antibody, and rabbit antibody. Further, the antibody of the present invention may be a chimeric antibody, a humanized antibody, a fully humanized antibody or the like.
具体的には、抗体を酵素、例えば、パパイン、ペプシンで処理し抗体断片を生成させるか、又は、これら抗体断片をコードする遺伝子を構築し、これを発現ベクターに導入した後、適当な宿主細胞で発現させる(例えば、Co, M.S. et al., J. Immunol. (1994) 152, 2968-2976、Better, M. & Horwitz, A. H. Methods in Enzymology (1989) 178, 476-496 、Plueckthun, A. & Skerra, A. Methods in Enzymology (1989) 178, 497-515 、Lamoyi, E., Methods in Enzymology (1989) 121, 652-663 、Rousseaux, J. et al., Methods in Enzymology (1989) 121, 663-66、Bird, R. E. et al., TIBTECH (1991) 9, 132-137参照)。 Specifically, the antibody is treated with an enzyme such as papain or pepsin to generate an antibody fragment, or a gene encoding these antibody fragments is constructed and introduced into an expression vector, and then an appropriate host cell is used. (For example, Co, MS et al., J. Immunol. (1994) 152, 2968-2976, Better, M. & Horwitz, AH Methods in Enzymology (1989) 178, 476-496, Plueckthun, A. & Skerra, A. Methods in Enzymology (1989) 178, 497-515, Lamoyi, E., Methods in Enzymology (1989) 121, 652-663, Rousseaux, J. et al., Methods in Enzymology (1989) 121, See 663-66, Bird, RE et al., TIBTECH (1991) 9, 132-137).
従って、本発明は、本発明のポリペプチドをコードするポリヌクレオチドが導入されたベクターを含む宿主細胞を培養する工程を含む、本発明のポリペプチド又は本発明のポリペプチドをコードする遺伝子によりコードされるポリペプチドを製造する方法を提供する。 Accordingly, the invention is encoded by a polypeptide of the invention or a gene encoding a polypeptide of the invention, comprising the step of culturing a host cell containing a vector into which the polypeptide encoding the polypeptide of the invention has been introduced. A method for producing a polypeptide is provided.
より具体的には、以下の工程を含む本発明のポリペプチドの製造方法を提供する。
(a)本発明のポリペプチドをコードする遺伝子が導入されたベクターを含む宿主細胞を培養する工程、
(b)当該遺伝子によりコードされるポリペプチドを取得する工程。
More specifically, the present invention provides a method for producing a polypeptide of the present invention, which comprises the following steps.
(a) A step of culturing a host cell containing a vector into which a gene encoding the polypeptide of the present invention has been introduced.
(b) The step of obtaining the polypeptide encoded by the gene.
scFvは、抗体のH鎖V領域とL鎖V領域を連結することにより得られる。このscFvにおいて、H鎖V領域とL鎖V領域はリンカー、好ましくは、ペプチドリンカーを介して連結される(Huston, J. S. et al.、Proc. Natl. Acad. Sci. U.S.A. (1988) 10.0, 5879-5883)。scFvにおけるH鎖V領域およびL鎖V領域は、上記抗体として記載されたもののいずれの由来であってもよい。V領域を連結するペプチドリンカーとしては、例えばアミノ酸12-19残基からなる任意の一本鎖ペプチドが用いられる。 scFv is obtained by linking the H chain V region and the L chain V region of an antibody. In this scFv, the H chain V region and the L chain V region are linked via a linker, preferably a peptide linker (Huston, JS et al., Proc. Natl. Acad. Sci. USA (1988) 10.0, 5879. -5883). The H chain V region and the L chain V region in scFv may be derived from any of the antibodies described above. As the peptide linker linking the V region, for example, any single-strand peptide consisting of amino acid 12-19 residues is used.
本発明の抗IL-6受容体抗体が定常領域を含む場合、定常領域は如何なるタイプの定常領域でもよく、例えばIgG1、IgG2、IgG4などの定常領域を用いることができる。定常領域はヒト抗体の定常領域であることが好ましい。又、ヒトIgG1、ヒトIgG2、ヒトIgG4などの定常領域に対してアミノ酸配列の置換、欠失、付加および/または挿入等を行った改変体であってもよい。 When the anti-IL-6 receptor antibody of the present invention contains a constant region, the constant region may be any type of constant region, and constant regions such as IgG1, IgG2, and IgG4 can be used. The constant region is preferably the constant region of a human antibody. Further, it may be a variant obtained by substituting, deleting, adding and / or inserting an amino acid sequence to a constant region such as human IgG1, human IgG2, or human IgG4.
本発明の抗IL-6受容体抗体が結合するIL-6受容体はヒトIL-6受容体であることが好ましい。 The IL-6 receptor to which the anti-IL-6 receptor antibody of the present invention binds is preferably a human IL-6 receptor.
本発明の抗IL-6受容体抗体は、血漿中滞留性に優れている抗体であり、抗IL-6受容体抗体が抗原である可溶型IL-6受容体および膜型IL-6受容体に結合可能な状態で血漿中に存在する時間が延長し、生体内の可溶型IL-6受容体および膜型IL-6受容体が抗IL-6受容体抗体によって結合されている時間が延長した抗体である。又、当該抗IL-6受容体抗体は、IL-6受容体に2回以上結合することが可能であり、3つ以上のIL-6受容体を中和することが可能であると考えられる。 The anti-IL-6 receptor antibody of the present invention is an antibody having excellent retention in plasma, and the soluble IL-6 receptor and the membrane type IL-6 receptor whose antigen is the anti-IL-6 receptor antibody. The time that the soluble IL-6 receptor and the membranous IL-6 receptor in vivo are bound by the anti-IL-6 receptor antibody is extended by prolonging the time that the antibody can be bound to the body. Is an extended antibody. Further, it is considered that the anti-IL-6 receptor antibody can bind to the IL-6 receptor more than once and can neutralize three or more IL-6 receptors. ..
<医薬組成物>
また本発明は、本発明の抗原結合分子、本発明のスクリーニング方法により単離された抗原結合分子、または本発明の製造方法により製造された抗原結合分子を含む医薬組成物に関する。本発明の抗原結合分子または本発明の製造方法により製造された抗原結合分子は血漿中滞留性に優れており、抗原結合分子の投与頻度を減らせることが期待されるので医薬組成物として有用である。本発明の医薬組成物は医薬的に許容される担体を含むことができる。
<Pharmaceutical composition>
The present invention also relates to a pharmaceutical composition containing an antigen-binding molecule of the present invention, an antigen-binding molecule isolated by the screening method of the present invention, or an antigen-binding molecule produced by the production method of the present invention. The antigen-binding molecule of the present invention or the antigen-binding molecule produced by the production method of the present invention has excellent retention in plasma and is expected to reduce the administration frequency of the antigen-binding molecule, and is therefore useful as a pharmaceutical composition. is there. The pharmaceutical composition of the present invention can include a pharmaceutically acceptable carrier.
本発明において医薬組成物とは、通常、疾患の治療もしくは予防、あるいは検査・診断のための薬剤を言う。 In the present invention, the pharmaceutical composition usually refers to a drug for treating or preventing a disease, or for testing / diagnosis.
本発明の医薬組成物は、当業者に公知の方法で製剤化することが可能である。例えば、水もしくはそれ以外の薬学的に許容し得る液との無菌性溶液、又は懸濁液剤の注射剤の形で非経口的に使用できる。例えば、薬理学上許容される担体もしくは媒体、具体的には、滅菌水や生理食塩水、植物油、乳化剤、懸濁剤、界面活性剤、安定剤、香味剤、賦形剤、ベヒクル、防腐剤、結合剤などと適宜組み合わせて、一般に認められた製薬実施に要求される単位用量形態で混和することによって製剤化することが考えられる。これら製剤における有効成分量は、指示された範囲の適当な容量が得られるように設定する。 The pharmaceutical composition of the present invention can be formulated by a method known to those skilled in the art. For example, it can be used parenterally in the form of a sterile solution with water or other pharmaceutically acceptable liquid, or an injectable suspension. For example, pharmacologically acceptable carriers or vehicles, specifically sterile water or saline, vegetable oils, emulsifiers, suspensions, surfactants, stabilizers, flavoring agents, excipients, vehicles, preservatives. , It is conceivable to formulate by appropriately combining with a binder and the like and mixing in a unit dose form required for generally accepted pharmaceutical practice. The amount of the active ingredient in these preparations is set so as to obtain an appropriate volume in the specified range.
注射のための無菌組成物は注射用蒸留水のようなベヒクルを用いて通常の製剤実施に従って処方することができる。 Aseptic compositions for injection can be formulated according to routine formulation practices using vehicles such as distilled water for injection.
注射用の水溶液としては、例えば生理食塩水、ブドウ糖やその他の補助薬(例えばD-ソルビトール、D-マンノース、D-マンニトール、塩化ナトリウム)を含む等張液が挙げられる。適当な溶解補助剤、例えばアルコール(エタノール等)、ポリアルコール(プロピレングリコール、ポリエチレングリコール等)、非イオン性界面活性剤(ポリソルベート80(TM)、HCO-50等)を併用してもよい。 Aqueous solutions for injection include, for example, saline, isotonic solutions containing glucose and other adjuvants (eg, D-sorbitol, D-mannose, D-mannitol, sodium chloride). Appropriate solubilizing agents such as alcohol (ethanol, etc.), polyalcohol (propylene glycol, polyethylene glycol, etc.), and nonionic surfactant (polysorbate 80 (TM), HCO-50, etc.) may be used in combination.
油性液としてはゴマ油、大豆油があげられ、溶解補助剤として安息香酸ベンジル及び/またはベンジルアルコールを併用してもよい。また、緩衝剤(例えば、リン酸塩緩衝液及び酢酸ナトリウム緩衝液)、無痛化剤(例えば、塩酸プロカイン)、安定剤(例えば、ベンジルアルコール及びフェノール)、酸化防止剤と配合してもよい。調製された注射液は通常、適当なアンプルに充填する。 Examples of the oily liquid include sesame oil and soybean oil, and benzyl benzoate and / or benzyl alcohol may be used in combination as a solubilizing agent. It may also be blended with a buffer (eg, phosphate buffer and sodium acetate buffer), a soothing agent (eg, procaine hydrochloride), a stabilizer (eg, benzyl alcohol and phenol), and an antioxidant. The prepared injection solution is usually filled in a suitable ampoule.
本発明の医薬組成物は、好ましくは非経口投与により投与される。例えば、注射剤型、経鼻投与剤型、経肺投与剤型、経皮投与型の組成物とすることができる。例えば、静脈内注射、筋肉内注射、腹腔内注射、皮下注射などにより全身または局部的に投与することができる。 The pharmaceutical composition of the present invention is preferably administered by parenteral administration. For example, it can be an injection type, a nasal administration type, a pulmonary administration type, or a transdermal administration type composition. For example, it can be administered systemically or locally by intravenous injection, intramuscular injection, intraperitoneal injection, subcutaneous injection, or the like.
投与方法は、患者の年齢、症状により適宜選択することができる。抗原結合分子含有する医薬組成物の投与量は、例えば、一回につき体重1 kgあたり0.0001 mgから1000 mgの範囲に設定することが可能である。または、例えば、患者あたり0.001〜100000 mgの投与量とすることもできるが、本発明はこれらの数値に必ずしも制限されるものではない。投与量及び投与方法は、患者の体重、年齢、症状などにより変動するが、当業者であればそれらの条件を考慮し適当な投与量及び投与方法を設定することが可能である。 The administration method can be appropriately selected depending on the age and symptoms of the patient. The dose of the pharmaceutical composition containing the antigen-binding molecule can be set, for example, in the range of 0.0001 mg to 1000 mg per kg of body weight at a time. Alternatively, for example, the dose may be 0.001 to 100,000 mg per patient, but the present invention is not necessarily limited to these values. The dose and administration method vary depending on the weight, age, symptoms, etc. of the patient, but those skilled in the art can set an appropriate dose and administration method in consideration of these conditions.
なお、本発明で記載されているアミノ酸配列に含まれるアミノ酸は翻訳後に修飾(例えば、N末端のグルタミンのピログルタミル化によるピログルタミン酸への修飾は当業者によく知られた修飾である)を受ける場合もあるが、そのようにアミノ酸が翻訳後修飾された場合であっても当然のことながら本発明で記載されているアミノ酸配列に含まれる。 The amino acids contained in the amino acid sequence described in the present invention are modified after translation (for example, modification of N-terminal glutamine to pyroglutamylation by pyroglutamylation is a modification well known to those skilled in the art). In some cases, even if the amino acid is post-translationally modified in this way, it is naturally included in the amino acid sequence described in the present invention.
なお本明細書において引用されたすべての先行技術文献は、参照として本明細書に組み入れられる。 All prior art documents cited herein are incorporated herein by reference.
以下本発明を実施例により具体的に説明するが、本発明はこれら実施例に制限されるものではない。 Hereinafter, the present invention will be specifically described with reference to Examples, but the present invention is not limited to these Examples.
〔実施例1〕改変ヒト化PM1抗体の作製
組み換え可溶型ヒトIL-6レセプター(SR344)の調製
抗原であるヒトIL-6レセプターの組み換えヒトIL-6レセプターは以下のように調製した。J.Biochem. 108, 673-676 (1990)で報告されているN末端側1番目から344番目のアミノ酸配列からなる可溶型ヒトIL-6レセプター(以下、SR344)(Yamasakiら、Science 1988;241:825-828 (GenBank # X12830))のCHO細胞定常発現株を作製した。
[Example 1] Preparation of modified humanized PM1 antibody
Preparation of recombinant soluble human IL-6 receptor (SR344) The recombinant human IL-6 receptor of human IL-6 receptor, which is an antigen, was prepared as follows. Soluble human IL-6 receptor (SR344) consisting of the N-terminal 1st to 344th amino acid sequences reported in J. Biochem. 108, 673-676 (1990) (Yamasaki et al., Science 1988; 241: 825-828 (GenBank # X12830)) CHO cell constant expression strain was prepared.
SR344発現CHO細胞から得られた培養上清から、Blue Sepharose 6 FFカラムクロマトグラフィー、SR344に対する特異抗体を固定したカラムによるアフィニティクロマトグラフィー、ゲルろ過カラムクロマトグラフィーの3つのカラムクロマトグラフィーにより、SR344を精製した。メインピークとして溶出した画分を最終精製品とした。
From the culture supernatant obtained from SR344-expressing CHO cells, SR344 was purified by three column chromatography:
組み換えカニクイザル可溶型IL-6レセプター(cIL-6R)の調製
公開されているアカゲザルIL-6レセプター遺伝子配列(Birney et al, Ensembl 2006, Nucleic Acids Res. 2006 Jan 1;34(Database issue):D556-61.)を元にオリゴDNAプライマー Rhe6Rf1(配列番号:16)、Rhe6Rr2(配列番号:17)を作製した。カニクイザル膵臓から調製されたcDNAを鋳型とし、プライマーRhe6Rf1およびRhe6Rr2を用いて、PCR法によりカニクイザルIL-6レセプター遺伝子全長をコードするDNA断片を調製した。得られたDNA断片を鋳型に、オリゴDNAプライマーCynoIL6R N-EcoRI(配列番号:18)およびCynoIL6R C-NotI-His(配列番号:19)を用いて、PCR法によりカニクイザルIL-6レセプター遺伝子のシグナル領域を含む可溶型領域(Met1-Pro363)のC末端に6xHisが付加されたタンパク質をコードする1131 bpのDNA断片(配列番号:20)を増幅した。得られたDNA断片をEcoRI-NotIで消化し、動物細胞発現ベクターへ挿入し、これを用いてCHO定常発現株(cyno.sIL-6R産生CHO細胞)を作製した。
Preparation of recombinant cynomolgus monkey soluble IL-6 receptor (cIL-6R) Published rhesus monkey IL-6 receptor gene sequence (Birney et al, Ensembl 2006, Nucleic Acids Res. 2006
cyno.sIL-6R産生CHO細胞の培養液をHisTrapカラム(GEヘルスケアバイオサイエンス)で精製後、Amicon Ultra-15 Ultracel-10k(Millipore)を用いて濃縮し、Superdex200pg16/60ゲルろ過カラム(GEヘルスケアバイオサイエンス)でさらに精製を行い、可溶型カニクイザルIL-6レセプター(以下、cIL-6R)の最終精製品とした。
Cultures of cyno.s IL-6R-producing CHO cells are purified on a HisTrap column (GE Healthcare Bioscience), concentrated using Amicon Ultra-15 Ultracel-10k (Millipore), and
組み換えカニクイザルIL-6(cIL-6)の調製
カニクイザルIL-6は以下のように調製した。SWISSPROT Accession No.P79341に登録されている212アミノ酸をコードする塩基配列を作成し、動物細胞発現ベクターにクローニングし、CHO細胞に導入することで定常発現細胞株を作製した(cyno.IL-6産生CHO細胞)。cyno.IL-6産生CHO細胞の培養液をSP-Sepharose/FFカラム(GEヘルスケアバイオサイエンス)で精製後、Amicon Ultra-15 Ultracel-5k(Millipore)を用いて濃縮し、Superdex75pg26/60ゲルろ過カラム(GEヘルスケアバイオサイエンス)でさらに精製を行い、Amicon Ultra-15 Ultracel-5k(Millipore)を用いて濃縮し、カニクイザルIL-6(以下、cIL-6)の最終精製品とした。
Preparation of recombinant cynomolgus monkey IL-6 (cIL-6) Cynomolgus monkey IL-6 was prepared as follows. A nucleotide sequence encoding 212 amino acids registered in SWISSPROT Accession No. P79341 was prepared, cloned into an animal cell expression vector, and introduced into CHO cells to prepare a constantly expressed cell line (cyno.IL-6 production). CHO cells). The culture medium of cyno.IL-6-producing CHO cells is purified by SP-Sepharose / FF column (GE Healthcare Bioscience), concentrated using Amicon Ultra-15 Ultracel-5k (Millipore), and filtered by Superdex75 pg26 / 60 gel. Further purification was carried out on a column (GE Healthcare Bioscience) and concentrated using Amicon Ultra-15 Ultracel-5k (Millipore) to prepare the final refined product of Crab Quizal IL-6 (hereinafter, cIL-6).
ヒトgp130発現BaF3細胞株の樹立
IL-6依存増殖性を示す細胞株を得るために、以下に示すとおり、ヒトgp130を発現したBaF3細胞株の樹立を行った。
Establishment of human gp130-expressing BaF3 cell line
In order to obtain a cell line showing IL-6-dependent proliferation, a BaF3 cell line expressing human gp130 was established as shown below.
全長ヒトgp130 cDNA(Hibiら、Cell 1990;63:1149-1157 (GenBank # NM_002184))をPCR法により増幅し、pCHOI(Hirataら、FEBS Letter 1994;356:244-248)のDHFR遺伝子発現部位を除去し、Zeocin耐性遺伝子発現部位を挿入した発現ベクターpCOS2Zeoにクローニングし、pCOS2Zeo/gp130を構築した。全長ヒトIL-6R cDNAをPCR法により増幅し、pcDNA3.1(+)(Invitrogen)にクローニングし、hIL-6R/pcDNA3.1(+)を構築した。10μgのpCOS2Zeo/gp130をPBSに懸濁したBaF3細胞(0.8x107 cells)に混合し、Gene Pulser(Bio-Rad)を用いて0.33 kV, 950μFDの容量でパルスを加えた。エレクトロポーレーション処理により遺伝子導入したBaF3細胞を0.2 ng/mLのmouse interleukin-3(Peprotech)、10% Fetal Bovine Serum(以下FBS、HyClone)を含むRPMI1640培地(Invitrogen)で一昼夜培養し、100 ng/mLのhuman interleukin-6(R&D systems)、100 ng/mL のhuman interleukin-6 soluble receptor(R&D systems)および10% FBSを含むRPMI1640培地を加えて選抜し、ヒトgp130発現BaF3細胞株(以下、BaF3/gp130)を樹立した。このBaF/gp130は、human interleukin-6(R&D systems)およびSR344存在下で増殖することから、抗IL-6レセプター抗体の増殖阻害活性(すなわちIL-6レセプター中和活性)の評価に使用することが可能である。 Full-length human gp130 cDNA (Hibi et al., Cell 1990; 63: 1149-1157 (GenBank # NM_002184)) was amplified by PCR to determine the DHFR gene expression site of pCHOI (Hirata et al., FEBS Letter 1994; 356: 244-248). The pCOS2Zeo / gp130 was constructed by removing it and cloning it into the expression vector pCOS2Zeo in which the Zeocin resistance gene expression site was inserted. A full-length human IL-6R cDNA was amplified by PCR and cloned into pcDNA3.1 (+) (Invitrogen) to construct hIL-6R / pcDNA3.1 (+). 10 μg of pCOS2Zeo / gp130 was mixed with BaF3 cells (0.8x10 7 cells) suspended in PBS and pulsed using Gene Pulser (Bio-Rad) at a volume of 0.33 kV, 950 μFD. BaF3 cells transgeniced by electroporation were cultured in RPMI1640 medium (Invitrogen) containing 0.2 ng / mL mouse interleukin-3 (Peprotech) and 10% Fetal Bovine Serum (FBS, HyClone) overnight and 100 ng / Selection was performed by adding mL of human interleukin-6 (R & D systems), 100 ng / mL of human interleukin-6 soluble receptor (R & D systems) and RPMI1640 medium containing 10% FBS, and human gp130-expressing BaF3 cell line (hereinafter, BaF3). / gp130) was established. Since this BaF / gp130 proliferates in the presence of human interleukin-6 (R & D systems) and SR344, it should be used to evaluate the growth inhibitory activity of anti-IL-6 receptor antibody (that is, IL-6 receptor neutralizing activity). Is possible.
ヒト化抗IL-6レセプター抗体の作製
Cancer Res. 1993 Feb 15;53(4):851-6においてヒト化されたマウスPM1抗体(以降Wild type、WTと略、H鎖WTをH(WT)(アミノ酸配列 配列番号:9)とし、L鎖WTをL(WT)(アミノ酸配列 配列番号:10)とする)のフレームワーク配列とCDR配列に変異を導入し、改変H鎖としてH53(アミノ酸配列 配列番号:1)、PF1H(アミノ酸配列 配列番号:11)、改変L鎖としてL28(アミノ酸配列 配列番号:12)、PF1L(アミノ酸配列 配列番号:2)を作製した。具体的には、QuikChange Site-Directed Mutagenesis Kit(Stratagene)を用いて、添付説明書記載の方法で変異体を作製し、得られたプラスミド断片を動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。
Preparation of humanized anti-IL-6 receptor antibody
Cancer Res. 1993
ヒト化抗IL-6レセプター抗体の発現と精製
抗体の発現は以下の方法を用いて行った。ヒト胎児腎癌細胞由来HEK293H株(Invitrogen)を10 % Fetal Bovine Serum(Invitrogen)を含むDMEM培地(Invitrogen)へ懸濁し、5〜6 × 105個 /mLの細胞密度で接着細胞用ディッシュ(直径10 cm, CORNING)の各ディッシュへ10 mLずつ蒔きこみCO2インキュベーター(37℃、5 % CO2)内で一昼夜培養した後に、培地を吸引除去し、CHO-S-SFM-II(Invitrogen)培地6.9 mLを添加した。調製したプラスミドをlipofection法により細胞へ導入した。得られた培養上清を回収した後、遠心分離(約2000 g、5分間、室温)して細胞を除去し、さらに0.22μmフィルターMILLEX(R)-GV(Millipore)を通して滅菌して培養上清を得た。得られた培養上清にrProtein A SepharoseTM Fast Flow(Amersham Biosciences)を用いて当業者公知の方法で精製した。精製抗体濃度は、分光光度計を用いて280 nmでの吸光度を測定した。得られた値からPACE法により算出された吸光係数を用いて抗体濃度を算出した(Protein Science 1995 ; 4 : 2411-2423)。
The expression of the humanized anti-IL-6 receptor antibody and the expression of the purified antibody were carried out by the following methods. Human fetal bovine cancer cell-derived HEK293H strain (Invitrogen) is suspended in DMEM medium (Invitrogen) containing 10% Fetal Bovine Serum (Invitrogen), and a dish for adherent cells (diameter) at a cell density of 5 to 6 × 10 5 cells / mL.
〔実施例2〕pH依存的結合抗体H3pI/L73の作製
複数回抗原を中和できる抗体の創製方法
IgG分子は2価であるため2ヶ所で抗原に結合した場合、1分子のIgG分子で最大2分子の抗原を中和することが可能であるが、3分子以上の抗原を中和することは出来ない。そのため中和抗体の場合、その中和効果を一定期間持続させるためには、その一定期間に産生される抗原量以上の抗体量が投与される必要があり、抗体の薬物動態向上やアフィニティー向上技術だけでは、必要抗体投与量の低減には限界が存在する。そこで1分子のIgG分子で2分子以上の抗原を中和することができれば、同じ投与量であれば中和効果の持続性が向上し、また、同じ持続性を達成するために必要な投与量を低減することが可能である。
[Example 2] Preparation of pH-dependent binding antibody H3pI / L73
Method for creating an antibody that can neutralize an antigen multiple times
Since an IgG molecule is divalent, when it binds to an antigen at two locations, it is possible to neutralize up to two antigens with one IgG molecule, but it is not possible to neutralize three or more antigens. Can not. Therefore, in the case of a neutralizing antibody, in order to maintain the neutralizing effect for a certain period of time, it is necessary to administer an antibody amount equal to or greater than the amount of the antigen produced in the certain period, and the technique for improving the pharmacokinetics and affinity of the antibody. There is a limit to the reduction of the required antibody dose by itself. Therefore, if one molecule of IgG molecule can neutralize two or more antigens, the sustainability of the neutralizing effect will be improved at the same dose, and the dose required to achieve the same persistence. Can be reduced.
中和抗体の場合、ターゲットとなる抗原の種類として、抗原が血漿中に存在する可溶型抗原場合と抗原が細胞表面に発現している膜型抗原の場合の2種類が存在する。 In the case of a neutralizing antibody, there are two types of target antigens: a soluble antigen in which the antigen is present in plasma and a membrane-type antigen in which the antigen is expressed on the cell surface.
抗原が膜型抗原の場合、投与した抗体は細胞表面上の膜抗原に結合して、その後、抗体は膜抗原に結合したまま抗原と一緒にインターナライゼーションによって細胞内のエンドソームに取り込まれ、その後、抗原に結合したままライソソームへ移行し抗体は抗原と一緒にライソソームにより分解される。膜抗原によるインターナライゼーションを介した血漿中から消失は抗原依存的な消失と呼ばれており、多くの抗体分子で報告されている(Drug Discov Today. 2006 Jan;11(1-2):81-8)。1分子のIgG抗体は2価で抗原に結合した場合2分子の抗原に結合し、インターナライズされそのままライソソームで分解されることから、通常の抗体の場合、1分子のIgG抗体が2分子以上の抗原を中和することは出来ない(図1)。 When the antigen is a membrane-type antigen, the administered antibody binds to the membrane antigen on the cell surface, and then the antibody is taken up by the intracellular endosome by internalization together with the antigen while being bound to the membrane antigen, and then. It migrates to the lysosome while still bound to the antigen, and the antibody is degraded by the lysosome together with the antigen. Elimination from plasma via internalization by membrane antigens is called antigen-dependent elimination and has been reported in many antibody molecules (Drug Discov Today. 2006 Jan; 11 (1-2): 81- 8). When one molecule of IgG antibody binds to an antigen with divalent value, it binds to two molecules of antigen, is internalized, and is decomposed by lysosome as it is. Therefore, in the case of a normal antibody, one molecule of IgG antibody has two or more molecules. Antigens cannot be neutralized (Fig. 1).
IgG分子の血漿中滞留性が長い(消失が遅い)のは、IgG分子のサルベージレセプターとして知られているFcRnが機能しているためである(Nat Rev Immunol. 2007 Sep;7(9):715-25)。ピノサイトーシスによってエンドソームに取り込まれたIgG分子は、エンドソーム内の酸性条件下においてエンドソーム内に発現しているFcRnに結合する。FcRnに結合できなかったIgG分子はライソソームへと進みそこで分解されるが、FcRnへ結合したIgG分子は細胞表面へ移行し血漿中の中性条件下においてFcRnから解離することで再び血漿中に戻る(図2)。 The long plasma retention (slow disappearance) of IgG molecules is due to the functioning of FcRn, which is known as a salvage receptor for IgG molecules (Nat Rev Immunol. 2007 Sep; 7 (9): 715. -twenty five). IgG molecules incorporated into endosomes by pinocytosis bind to FcRn expressed in endosomes under acidic conditions within endosomes. IgG molecules that could not bind to FcRn proceed to the lysosome and are degraded there, but IgG molecules that bind to FcRn migrate to the cell surface and dissociate from FcRn under neutral conditions in plasma, returning to plasma again. (Fig. 2).
膜抗原に結合したIgG分子はインターナライゼーションによって細胞内のエンドソームに取り込まれ、抗原に結合したままライソソームに移行し分解され、IgG抗体が2価で抗原に結合した場合は2分子の抗原を中和して抗原と共に分解される。インターナライゼーションによって細胞内のエンドソームに取り込まれた際に、エンドソーム内の酸性条件下においてIgG抗体が抗原から解離することが出来れば、解離した抗体はエンドソーム内に発現しているFcRnに結合することが出来ると考えられる。抗原から解離しFcRnへ結合したIgG分子は細胞表面へ移行し血漿中の中性条件下においてFcRnから解離することで再び血漿中に戻り、血漿中に戻ったIgG分子は再度新たな膜抗原へ結合することが可能である。これを繰り返すことによって、1分子のIgG分子が繰り返し膜型抗原に結合することが可能になるため、1分子のIgG分子が複数個の抗原を中和することが可能となる(図3)。 The IgG molecule bound to the membrane antigen is taken up by endosomes in the cell by internalization, transferred to the lysosome while bound to the antigen and decomposed, and when the IgG antibody binds to the antigen in divalent, the two molecules of the antigen are neutralized. And is degraded with the antigen. If the IgG antibody can dissociate from the antigen under acidic conditions in the endosome when it is taken up by the endosome in the cell by internalization, the dissociated antibody can bind to FcRn expressed in the endosome. It is thought that it can be done. The IgG molecule dissociated from the antigen and bound to FcRn migrates to the cell surface and dissociates from FcRn under neutral conditions in plasma to return to plasma again, and the IgG molecule returned to plasma becomes a new membrane antigen again. It is possible to combine. By repeating this, one molecule of IgG molecule can repeatedly bind to the membrane-type antigen, so that one molecule of IgG molecule can neutralize a plurality of antigens (FIG. 3).
抗原が可溶型抗原の場合、投与した抗体は血漿中で抗原に結合し、抗原と抗体の複合体の形で血漿中を滞留する。通常、抗体の血漿中滞留性は上述のとおりFcRnの機能により非常に長い(消失速度が非常に遅い)のに対して、抗原の血漿中滞留性は短い(消失速度が速い)ため、抗体に結合した抗原は抗体と同程度の血漿中滞留性を有する(消失が非常に遅い)ことになる。抗原は生体内で常に一定の速度で産生されており、抗体非存在下では抗原の産生速度と抗原の消失速度が釣り合った状態の濃度で抗原が血漿中に存在する。抗体存在下では、ほとんどの抗原が抗体に結合し、抗原の消失は非常に遅くなるため血漿中の抗原濃度は抗体非存在下に比べて上昇する(Kidney Int. 2003, 64, 697-703、J. National Cancer Institute 2002, 94(19), 1484-1493、J. Allergy and Clinical Immunology 1997, 100(1), 110-121、Eur. J. Immunol. 1993, 23; 2026-2029 )。仮に抗体の抗原へのアフィニティーが無限大であったとしても、抗原の濃度が上昇し、抗体が血漿中から徐々に消失し、抗体と抗原の濃度が一致した時間以降、抗体の抗原中和効果が切れてしまう。可溶型抗原に対する中和効果は、解離定数(KD)が強いほど少ない抗体濃度で中和することが可能であるが、アフィニティーをどれだけ強くしても存在する抗原濃度の1/2以下の抗体濃度では抗原を中和することができない(Biochem Biophys Res Commun. 2005 Sep 9;334(4):1004-13)。抗原が結合していないIgG分子同様、抗原が結合したIgG分子も血漿中においてピノサイトーシスによってエンドソームに取り込まれ、エンドソーム内の酸性条件下においてエンドソーム内に発現しているFcRnに結合する。FcRnへ結合したIgG分子は抗原に結合したまま、細胞表面へ移行し血漿中の中性条件下においてFcRnから解離することでIgG分子は抗原に結合したまま再び血漿中に戻るため、血漿中で新たな抗原に結合することは出来ない。この際、エンドソーム内の酸性条件下においてIgG分子が抗原から解離することが出来れば、解離した抗原はFcRnに結合することが出来ないため、その抗原はライソソームによって分解されると考えられる。一方、IgG分子はFcRnに結合することにより再び血漿中に戻ることが可能である。血漿中に戻ったIgG分子は、すでにエンドソーム内で抗原を解離していることから、血漿中において再度新しい抗原に結合することが可能になる。これを繰り返すことによって、1分子のIgG分子が繰り返し可溶型抗原に結合することが可能になるため、1分子のIgG分子が複数個の抗原を中和することが可能となる(図4)。
When the antigen is a soluble antigen, the administered antibody binds to the antigen in plasma and stays in plasma in the form of a complex of antigen and antibody. Normally, the plasma retention of an antibody is very long (the rate of elimination is very slow) due to the function of FcRn as described above, whereas the retention of an antigen in plasma is short (the rate of elimination is fast). The bound antigen will have the same plasma retention as the antibody (very slow to disappear). The antigen is always produced at a constant rate in the living body, and in the absence of the antibody, the antigen is present in plasma at a concentration in which the production rate of the antigen and the disappearance rate of the antigen are balanced. In the presence of the antibody, most of the antigens bind to the antibody, and the disappearance of the antigen is very slow, so that the antigen concentration in plasma is higher than that in the absence of the antibody (Kidney Int. 2003, 64, 697-703, J. National Cancer Institute 2002, 94 (19), 1484-1493, J. Allergy and Clinical Immunology 1997, 100 (1), 110-121, Eur. J. Immunol. 1993, 23; 2026-2029). Even if the affinity of the antibody for the antigen is infinite, the antigen-neutralizing effect of the antibody will increase after the time when the antibody concentration increases, the antibody gradually disappears from the plasma, and the antibody-antigen concentration matches. Will run out. The neutralizing effect on soluble antigens can be neutralized with a smaller antibody concentration as the dissociation constant (KD) is stronger, but it is less than 1/2 of the existing antigen concentration no matter how strong the affinity is. Antigens cannot be neutralized at antibody concentrations (Biochem Biophys Res Commun. 2005
このように抗原が膜型抗原、可溶型抗原であるに関わらず、エンドソーム内の酸性条件下においてIgG抗体が抗原から解離することが出来れば、1分子のIgG分子が繰り返し抗原を中和することが達成できると考えられた。エンドソーム内の酸性条件下においてIgG抗体が抗原から解離するためには、酸性条件下において抗原と抗体の結合が中性条件下と比較して大幅に弱くなる必要がある。細胞表面では膜抗原を中和する必要があるため、細胞表面のpHであるpH7.4においては抗原に強く結合する必要がある。エンドソーム内のpHは一般的にpH5.5〜pH6.0であることが報告されている(Nat Rev Mol Cell Biol. 2004 Feb;5(2):121-32.)ことから、pH5.5〜pH6.0において抗原に弱く結合する抗体であれば、エンドソーム内の酸性条件下において抗原から抗体は解離すると考えられる。すなわち、細胞表面のpHであるpH7.4においては抗原に強く結合し、エンドソーム内のpHであるpH5.5〜pH6.0において抗原に弱く結合する抗体であれば、1分子のIgG分子が複数個の抗原を中和し、薬物動態を向上することが可能であると考えられた。 In this way, regardless of whether the antigen is a membrane-type antigen or a soluble-type antigen, if the IgG antibody can be dissociated from the antigen under acidic conditions in the endosome, one IgG molecule repeatedly neutralizes the antigen. Was thought to be achievable. In order for the IgG antibody to dissociate from the antigen under acidic conditions in endosomes, the binding between the antigen and the antibody under acidic conditions needs to be significantly weaker than under neutral conditions. Since it is necessary to neutralize the membrane antigen on the cell surface, it is necessary to strongly bind to the antigen at pH 7.4, which is the pH of the cell surface. It has been reported that the pH in endosomes is generally pH 5.5 to pH 6.0 (Nat Rev Mol Cell Biol. 2004 Feb; 5 (2): 121-32.). An antibody that binds weakly to the antigen at pH 6.0 is considered to dissociate from the antigen under acidic conditions within the endosome. That is, if the antibody binds strongly to the antigen at pH 7.4, which is the pH of the cell surface, and weakly binds to the antigen at pH 5.5 to pH 6.0, which is the pH inside the endosome, one molecule of IgG molecule is plural. It was considered possible to neutralize individual antigens and improve pharmacokinetics.
一般的にタンパク質−タンパク質相互作用は疎水相互作用、静電相互作用、水素結合からなり、その結合の強さは一般的に結合定数(affinity)、あるいは見かけの結合定数(avidity)で表現される。中性条件下(pH7.4)と酸性条件下(pH5.5〜pH6.0)とで結合の強さが変化するpH依存的な結合は、天然に存在するタンパク質−タンパク質相互作用に存在する。例えば上述したIgG分子とIgG分子のサルベージレセプターとして知られているFcRnの結合は、酸性条件下(pH5.5〜pH6.0)で強く結合し中性条件下(pH7.4)で極めて結合が弱い。これら多くのpH依存的に結合が変化するタンパク質−タンパク質相互作用においては、その相互作用にヒスチジン残基が関与している。ヒスチジン残基のpKaは6.0〜6.5付近に存在するため、中性条件下(pH7.4)と酸性条件下(pH5.5〜pH6.0)との間でヒスチジン残基のプロトンの解離状態が変化する。すなわち、ヒスチジン残基は中性条件下(pH7.4)においては電荷を帯びず中性で水素原子アクセプターとして機能し、酸性条件下(pH5.5〜pH6.0)においては正電荷を帯び水素原子ドナーとして機能する。上述のIgG-FcRn相互作用においても、IgG側に存在するヒスチジン残基がpH依存的結合に関与していることが報告されている(Mol Cell. 2001 Apr;7(4):867-77.)。 In general, protein-protein interaction consists of hydrophobic interaction, electrostatic interaction, and hydrogen bond, and the strength of the bond is generally expressed by the binding constant (affinity) or apparent binding constant (avidity). .. The strength of the bond changes between neutral (pH 7.4) and acidic conditions (pH 5.5 to pH 6.0) pH-dependent binding is present in naturally occurring protein-protein interactions. .. For example, the above-mentioned binding between an IgG molecule and FcRn, which is known as a salvage receptor for an IgG molecule, strongly binds under acidic conditions (pH 5.5 to pH 6.0) and extremely binds under neutral conditions (pH 7.4). weak. In many of these pH-dependent protein-protein interactions, histidine residues are involved in the interaction. Since the pKa of histidine residue is around 6.0 to 6.5, the proton dissociation state of histidine residue is between neutral conditions (pH 7.4) and acidic conditions (pH 5.5 to pH 6.0). Change. That is, the histidine residue is neutral and functions as a hydrogen atom acceptor under neutral conditions (pH 7.4), and is positively charged under acidic conditions (pH 5.5 to pH 6.0). Functions as an atomic donor. It has been reported that the histidine residue present on the IgG side is involved in pH-dependent binding in the above-mentioned IgG-FcRn interaction (Mol Cell. 2001 Apr; 7 (4): 867-77. ).
そのためタンパク質−タンパク質相互作用に関与するアミノ酸残基をヒスチジン残基に置換する、あるいは、相互作用する箇所にヒスチジンを導入することによってタンパク質−タンパク質相互作用にpH依存性を付与することは可能である。抗体−抗原間のタンパク質−タンパク質相互作用においてもそのような試みがされており、抗卵白リゾチウム抗体のCDR配列にヒスチジンを導入することによって、酸性条件下で抗原に対する結合性が低下した抗体変異体を取得することに成功している(FEBS Letter (vol.309, No.1, 85-88, 1992))。また、CDR配列にヒスチジンを導入することによって、ガン組織の低いpHで特異的に抗原に結合し中性条件下では弱く結合する抗体が報告されている(WO2003105757)。 Therefore, it is possible to impart pH dependence to the protein-protein interaction by substituting the amino acid residue involved in the protein-protein interaction with a histidine residue, or by introducing histidine at the site of interaction. .. Such attempts have also been made in protein-protein interactions between antibody-antigen, and antibody variants whose binding to antigen has been reduced under acidic conditions by introducing histidine into the CDR sequences of anti-egg white lysodium antibodies. Has been successfully obtained (FEBS Letter (vol.309, No.1, 85-88, 1992)). In addition, an antibody that specifically binds to an antigen at a low pH of a cancer tissue and weakly binds to a neutral condition by introducing histidine into a CDR sequence has been reported (WO2003105757).
このように抗原抗体反応にpH依存性を導入する方法は報告されているが、これまでに体液中のpHであるpH7.4においては抗原に強く結合し、エンドソーム内のpHであるpH5.5〜pH6.0において抗原に弱く結合することで、1分子のIgG分子が複数個の抗原を中和する抗体は報告されていない。すなわち、中性条件下での結合を維持しつつ酸性条件下での結合のみを大きく低下させる改変を導入することで、改変前の抗体と比較して改変後の抗体が、in vivoにおいて抗原に複数回結合することで薬物動態が向上し、同じ投与量で中和効果の持続性が向上した抗体の改変に関する報告は無い。 Although a method for introducing pH dependence into an antigen-antibody reaction has been reported in this way, it binds strongly to an antigen at pH 7.4, which is the pH in body fluids, and pH 5.5, which is the pH in endosomes. No antibody has been reported in which one IgG molecule neutralizes multiple antigens by weakly binding to the antigen at ~ pH 6.0. That is, by introducing a modification that significantly reduces only the binding under acidic conditions while maintaining the binding under neutral conditions, the modified antibody becomes an antigen in vivo as compared with the antibody before modification. There is no report on the modification of the antibody in which the pharmacokinetics is improved by binding multiple times and the duration of the neutralizing effect is improved at the same dose.
IL-6レセプターは生体内に可溶型IL-6レセプターおよび膜型IL-6レセプターの両方の形で存在する(Nat Clin Pract Rheumatol. 2006 Nov;2(11):619-26.)。抗IL-6レセプター抗体は可溶型IL-6レセプターおよび膜型IL-6レセプター両方に結合してそれらの生物学的な作用を中和する。抗IL-6レセプター抗体は膜型IL-6レセプターに結合後、膜型IL-6レセプターに結合したままインターナライゼーションによって細胞内のエンドソームに取り込まれ、その後、抗IL-6レセプター抗体は膜型IL-6レセプターに結合したままライソソームへ移行し一緒にライソソームにより分解されると考えられている。実際、ヒト化抗IL-6レセプター抗体は、非線形なクリアランスを示し、抗原依存的な消失がヒト化抗IL-6レセプター抗体の消失に大きく寄与していることが報告されている(The Journal of Rheumatology, 2003, 30;71426-1435)。すなわち、1分子のヒト化抗IL-6レセプター抗体は1分子ないしは2分子の膜型IL-6レセプターに(1価ないしは2価で)結合し、インターナライズ後、ライソソームで分解されると考えられる。そこで、天然型のヒト化抗IL-6レセプター抗体の中性条件下での結合を維持しつつ酸性条件下での結合のみを大きく低下させる改変抗体(pH依存的結合抗IL-6レセプター抗体)を作製することが出来れば、1分子のヒト化抗IL-6レセプター抗体で複数分子のIL-6レセプターを中和できると考えられ、これにより天然型のヒト化抗IL-6レセプター抗体と比較して、pH依存的結合抗IL-6レセプター抗体はin vivoにおいて同じ投与量で中和効果の持続性が向上できると考えた。 The IL-6 receptor exists in vivo in the form of both a soluble IL-6 receptor and a membrane IL-6 receptor (Nat Clin Pract Rheumatol. 2006 Nov; 2 (11): 619-26.). Anti-IL-6 receptor antibodies bind to both soluble and membrane IL-6 receptors and neutralize their biological effects. After binding to the membrane-type IL-6 receptor, the anti-IL-6 receptor antibody is taken up by intracellular endosomes while binding to the membrane-type IL-6 receptor, and then the anti-IL-6 receptor antibody is incorporated into the membrane-type IL-6. -6 It is thought that it migrates to the lysosome while still bound to the receptor and is degraded together by the lysosome. In fact, humanized anti-IL-6 receptor antibody exhibits non-linear clearance, and it has been reported that antigen-dependent elimination contributes significantly to the elimination of humanized anti-IL-6 receptor antibody (The Journal of). Rheumatology, 2003, 30; 71426-1435). That is, it is considered that one molecule of humanized anti-IL-6 receptor antibody binds to one or two molecules of membrane-type IL-6 receptor (in monovalent or divalent), and after internalization, it is degraded by lysosomes. .. Therefore, a modified antibody (pH-dependent binding anti-IL-6 receptor antibody) that significantly reduces only the binding under acidic conditions while maintaining the binding of the natural humanized anti-IL-6 receptor antibody under neutral conditions. It is considered that one molecule of humanized anti-IL-6 receptor antibody can neutralize multiple molecules of IL-6 receptor, which is compared with the natural humanized anti-IL-6 receptor antibody. Therefore, it was considered that the pH-dependent binding anti-IL-6 receptor antibody can improve the persistence of the neutralizing effect in vivo at the same dose.
pH依存的結合ヒト化IL-6レセプター抗体H3pI/L73の作製
pH依存的な結合を抗原抗体反応に導入する方法として、CDRにヒスチジンを導入する方法が報告されている(FEBS Letter (vol.309, No.1, 85-88, 1992))。実施例1で作製したH53/PF1Lの可変領域表面に露出するアミノ酸残基および抗原と相互作用していると考えられる残基を確認するために、MOEソフトウェア(Chemical Computing Group Inc.)を用いて、ホモロジーモデリングによりH53/PF1LのFv領域モデルを作製した。H53/PF1Lの配列情報を元に作成した立体構造モデルより、ヒスチジン導入により抗原とのpH依存的結合を導入できると考えられる変異箇所をH27、H31、H35、L28、L32、L53(Kabatナンバリング、Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest.NIH)に選定した。H27、H31、H35の残基をヒスチジンに置換する変異を実施例1で作成したH53に対して導入したものをH3pI(アミノ酸配列 配列番号:3)とし、L28、L32、L53の残基をヒスチジンに置換する変異を実施例1で作成したPF1Lに対して導入したものをL73(アミノ酸配列 配列番号:6)とした。
Preparation of pH-dependent binding humanized IL-6 receptor antibody H3pI / L73
A method of introducing histidine into CDR has been reported as a method of introducing pH-dependent binding into an antigen-antibody reaction (FEBS Letter (vol.309, No.1, 85-88, 1992)). MOE software (Chemical Computing Group Inc.) was used to confirm the amino acid residues exposed on the surface of the variable region of H53 / PF1L prepared in Example 1 and the residues that are considered to interact with the antigen. , Fv region model of H53 / PF1L was prepared by homology modeling. From the three-dimensional structure model created based on the sequence information of H53 / PF1L, mutation sites that are thought to be able to introduce pH-dependent binding to the antigen by introducing histidine are H27, H31, H35, L28, L32, L53 (Kabat numbering, Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest. NIH). A mutation that replaces the residues of H27, H31, and H35 with histidine was introduced into H53 prepared in Example 1 as H3pI (amino acid sequence SEQ ID NO: 3), and the residues of L28, L32, and L53 were histidine. L73 (amino acid sequence SEQ ID NO: 6) was obtained by introducing a mutation to replace PF1L prepared in Example 1.
H3pI/L73の発現ベクターの作製・発現・精製
選定された箇所について改変抗体を作製するためのアミノ酸改変を行った。実施例1において作製したH53(塩基配列 配列番号:13)およびPF1L(塩基配列 配列番号:14)に変異を導入して、H3pI(アミノ酸配列 配列番号:3)とL73(アミノ酸配列 配列番号:6)を作製した。具体的には、QuikChange Site-Directed Mutagenesis Kit(Stratagene)を用いて、添付説明書記載の方法で作製し、得られたプラスミド断片を動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。H鎖としてH3pI、L鎖としてL73を用いたH3pI/L73の発現・精製は実施例1に記載した方法で行った。
Preparation / expression / purification of H3pI / L73 expression vector Amino acid modification was performed on the selected site to prepare a modified antibody. Mutations were introduced into H53 (nucleic acid sequence SEQ ID NO: 13) and PF1L (nucleic acid sequence SEQ ID NO: 14) prepared in Example 1, and H3pI (amino acid sequence SEQ ID NO: 3) and L73 (amino acid sequence SEQ ID NO: 6) were introduced. ) Was prepared. Specifically, it was prepared by the method described in the attached manual using the QuikChange Site-Directed Mutagenesis Kit (Stratagene), and the obtained plasmid fragment was inserted into an animal cell expression vector to obtain the target H chain expression vector and L. A chain expression vector was prepared. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art. The expression and purification of H3pI / L73 using H3pI as the H chain and L73 as the L chain was carried out by the method described in Example 1.
〔実施例3〕ファージディスプレイ技術を用いたCDR His改変によるpH依存的抗原結合能の付与
ヒト化PM1抗体のscFv分子の作製
ヒト化抗IL-6R抗体であるヒト化PM1抗体(Cancer Res. 1993 Feb 15;53(4):851-6)のscFv化を行った。VH、VL領域をPCRによって増幅し、リンカー配列GGGGSGGGGSGGGGS(配列番号:15)をVH、VLの間に持つヒト化PM1 HL scFvを作製した。
[Example 3] Addition of pH-dependent antigen-binding ability by CDR His modification using phage display technology
Preparation of scFv molecule of humanized PM1 antibody Humanized PM1 antibody (Cancer Res. 1993
ヒスチジンscanningによるヒスチジン導入可能箇所の選定
作製したヒト化PM1 HL scFv DNAを鋳型にしたPCRにより、各CDRアミノ酸のうちの一つのアミノ酸がヒスチジンとなるヒスチジンライブラリーを作製した。ライブラリー化したいアミノ酸のコドンをヒスチジンに相当するコドンであるCATとしたプライマーを用いたPCR反応によってライブラリー部分を構築、それ以外の部分を通常のPCRによって作製し、assemble PCR法により連結して構築した。構築したライブラリーをSfi Iで消化し、同様にSfi Iで消化したphagemideベクターpELBG lacIベクターに挿入し、XL1-Blue(stratagene)にtransformした。得られたコロニーを用い、phage ELISAによる抗原結合性評価とHL scFv配列解析を行った。J.Mol.Biol 1992 ; 227 : 381-388に習い、SR344を1μg/mLでcoatingしたプレートを用いたphage-ELISAを行った。SR344への結合性が認められたクローンについて、特異的プライマーを用い、配列解析を行った。
Selection of sites where histidine can be introduced by histidine scanning PCR using the prepared humanized PM1 HL scFv DNA as a template was used to prepare a histidine library in which one of the CDR amino acids is histidine. A library part is constructed by a PCR reaction using a primer in which the codon of the amino acid to be libraryized is CAT, which is a codon corresponding to histidine, and the other parts are prepared by ordinary PCR and linked by the assemble PCR method. It was constructed. The constructed library was digested with Sfi I, inserted into the phagemide vector pELBG lacI vector digested with Sfi I, and transformed into XL1-Blue (stratagene). Using the obtained colonies, antigen binding was evaluated by phage ELISA and HL scFv sequence analysis was performed. Following J. Mol.Biol 1992; 227: 381-388, phage-ELISA was performed using a plate coated with SR344 at 1 μg / mL. The clones that were found to bind to SR344 were sequenced using specific primers.
anti-Etag抗体(GE Healthcare)とanti-M13抗体(GE Healthcare)によるELISA法により、phage titerを求めた。この値を用い、SR344に対するphage ELISAの結果から、ヒト化PM1 HL scFvと比べ、CDRの残基をヒスチジンに置換しても結合能に大きな変化がない箇所を選定した。これらの箇所を表2に示した。各残基のナンバリングはKabatナンバリング(Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest.NIH)に従った。 The phage titer was determined by the ELISA method using anti-Etag antibody (GE Healthcare) and anti-M13 antibody (GE Healthcare). Using this value, from the results of phage ELISA for SR344, a site where there was no significant change in binding ability even when the CDR residue was replaced with histidine was selected as compared with humanized PM1 HL scFv. These points are shown in Table 2. The numbering of each residue was according to Kabat numbering (Kabat EA et al. 1991. Sequences of Proteins of Immunological Interest. NIH).
[表2]結合能に大きく影響のないヒスチジン置換箇所
H31, H50, H54, H56, H57, H58, H59, H60, H61, H62, H63, H64, H65, H100a, H100b, H102
L24, L26, L27, L28, L30, L31, L32, L52, L53, L54, L56, L90, L92, L93, L94
[Table 2] Histidine substitution site that does not significantly affect the binding ability
H31, H50, H54, H56, H57, H58, H59, H60, H61, H62, H63, H64, H65, H100a, H100b, H102
L24, L26, L27, L28, L30, L31, L32, L52, L53, L54, L56, L90, L92, L93, L94
CDRヒスチジン改変ライブラリーの構築
表2に示した、ヒスチジンに置換しても結合能に大きな変化がないCDR残基(ヒスチジン導入可能箇所)のアミノ酸を、元の配列(天然型配列)もしくはヒスチジンとなるライブラリーの設計を行った。実施例1で作製したH鎖PF1H、L鎖PF1Lの配列を元にし、ライブラリー箇所において、元の配列あるいはヒスチジン(元の配列かヒスチジンのどちらか一方)、となるようにライブラリーを構築した。
Construction of CDR histidine modification library The amino acid of the CDR residue (location where histidine can be introduced) shown in Table 2 whose binding ability does not change significantly even when replaced with histidine is replaced with the original sequence (natural sequence) or histidine. I designed the library. Based on the sequences of H chain PF1H and L chain PF1L prepared in Example 1, a library was constructed so as to be the original sequence or histidine (either the original sequence or histidine) at the library site. ..
ライブラリー化したい箇所を、元のアミノ酸のコドン、もしくはヒスチジンのコドン、となるよう設計したプライマーを用いたPCR反応によってライブラリー部分を構築、それ以外の場所を通常のPCR、もしくはライブラリー部分と同様に合成プライマーを用いたPCR反応によって作製し、assemble PCR法により連結して構築した(J.Mol.Biol 1996 ; 256 : 77-88)。 The library part is constructed by PCR reaction using a primer designed to be the codon of the original amino acid or the codon of histidine at the part to be made into a library, and the other part is the normal PCR or the library part. Similarly, it was prepared by PCR reaction using synthetic primers, and ligated by the assemble PCR method to construct it (J. Mol. Biol 1996; 256: 77-88).
このライブラリーを用い、J. Immunological Methods 1999 ;231:119-135に習い、ribosome display用ライブラリーを構築した。大腸菌無細胞系in vitro translationを行うために、SDA配列(ribosome binding site)、T7 promoterを5'側に付加し、ribosome display用のリンカーとして3'側にgene3部分配列をSfi Iを用いてligationした。 Using this library, I learned from J. Immunological Methods 1999; 231: 119-135 and built a library for ribosome display. In order to perform E. coli cell-free in vitro translation, SDA sequence (ribosome binding site) and T7 promoter are added to the 5'side, and gene3 partial sequence is ligated on the 3'side using Sfi I as a linker for ribosome display. did.
ビーズパンニングによるライブラリーからのpH依存的結合scFvの取得
SR344への結合能をもつscFvのみを濃縮させるため、Nature Biotechnology 2000 Dec ; 18 : 1287-1292 に習い、ribosome display法によるパンニングを2回行った。調製されたSR344を、NHS-PEO4-Biotin(Pierce)を用いてビオチン化し抗原とした。ビオチン化抗原量を40 nM使用し、パンニングを行った。
Acquisition of pH-dependent binding scFv from library by bead panning
In order to concentrate only scFv capable of binding to SR344, panning by the ribosome display method was performed twice according to Nature Biotechnology 2000 Dec; 18: 1287-1292. The prepared SR344 was biotinylated using NHS-PEO4-Biotin (Pierce) to prepare an antigen. Panning was performed using a biotinylated antigen amount of 40 nM.
得られたDNA poolを鋳型とし、特異的プライマーを用いてPCRすることによりHL scFvを復元した。Sfi Iで消化し、同様にSfi Iで消化したphagemideベクターpELBG lacIベクターに挿入し、XL1-Blue(stratagene)にtransformした。 HL scFv was restored by PCR using the obtained DNA pool as a template and specific primers. It was digested with Sfi I, inserted into the phagemide vector pELBG lacI vector digested with Sfi I, and transformed into XL1-Blue (stratagene).
目的のプラスミドを有する大腸菌を、2YT/100μg/mLアンピシリン/2% glucose培地中で0.4-0.6 O.D./mLまで増殖させた。そこにHelper phage(M13KO7, 4.5x1011pfu)を加え、37℃で30分間静置培養、37℃で30分間震盪培養を行った後、50 mL Falconチューブに移し3000 rpmで10分間遠心分離し、2YT/100μg/mLアンピシリン/25μg/mLカナマイシン/0.5 mM IPTG中に再懸濁し、そして30℃で一晩増殖させた。 E. coli with the plasmid of interest was grown to 0.4-0.6 OD / mL in 2YT / 100 μg / mL ampicillin / 2% glucose medium. Helper phage (M13KO7, 4.5x10 11 pfu) was added thereto, and the cells were statically cultured at 37 ° C for 30 minutes, shake-cultured at 37 ° C for 30 minutes, transferred to a 50 mL Falcon tube, and centrifuged at 3000 rpm for 10 minutes. , 2YT / 100 μg / mL ampicillin / 25 μg / mL canamycin / 0.5 mM IPTG resuspended and grown overnight at 30 ° C.
ファージ液は、一晩培養した培養液を2.5 M NaCl/10%PEGにより沈殿させた後PBSにて希釈しファージライブラリー液とした。ファージライブラリー液に10% M-PBS(10%スキムミルクを含むPBS)、1 M Tris-HClを加え、終濃度2.5% M-PBS, pH7.4とした。パンニングは、一般的な方法である磁気ビーズに固定化した抗原を用いたパンニング方法を用いた(J Immunol Methods. 2008 Mar 20;332(1-2):2-9.、J Immunol Methods. 2001 Jan 1;247(1-2):191-203.、Biotechnol Prog. 2002 Mar-Apr;18(2):212-20.)。具体的には、調製したファージライブラリーに40 pmolのビオチン標識SR344を加え、37℃で60分間抗原と接触させた。5% M-PBS(5%スキムミルクを含むPBS)で洗浄したStreptavidin coated beads(Dynal M-280)を加え、37℃で15分間結合させた。ビーズを0.5 mLのPBST(0.1% Tween-20を含むPBS, pH7.4)とPBS(pH7.4)にて5回ずつ洗浄した。1 mLのPBS(pH5.5)中にビーズを37℃で懸濁し、即にファージを回収した。回収したファージ溶液に、対数増殖期(OD600 0.4-0.5)XL1-Blue 10 mLに添加、37℃, 30分間静置することで感染させた。感染させた大腸菌を、2YT/100μg/mLアンピシリン/2% glucoseの225 mm x 225 mmのプレートへプレーティングした。再度この大腸菌から培養を開始し、上記と同様にファージの培養を行いパンニングを8回繰り返した。
The phage solution was prepared as a phage library solution by precipitating the culture solution cultured overnight with 2.5 M NaCl / 10% PEG and then diluting with PBS. 10% M-PBS (PBS containing 10% skim milk) and 1 M Tris-HCl were added to the phage library solution to give a final concentration of 2.5% M-PBS, pH 7.4. For panning, a panning method using an antigen immobilized on magnetic beads, which is a general method, was used (J Immunol Methods. 2008
ファージELISAによる評価
上記のシングルコロニーを100μL 2YT/100μg/mLアンピシリン/2% glucose/12.5μg/mLテトラサイクリンに植菌し、30℃で一晩培養した。この2μLを300μL 2YT/100μg/mLアンピシリン/2% glucoseに植菌、37℃、4時間培養後、ヘルパーファージ(M13KO7)9 x 108pfuを加え、37℃で30分間静置培養、37℃30分間攪拌培養をおこない感染させた。この後2YT/100μg/mLアンピシリン/25μg/mLカナマイシン/0.5 mM IPTG 300μLに培地交換を行った。続いて30℃にて一晩培養し、遠心上清を回収した。遠心上清40μLに50 mM PBS(pH7.4)360μL加え、ELISAに供した。StreptaWell 96マイクロタイタープレート(Roche)を62.5 ng/mLビオチン標識SR344を含むPBS 100μLにて一晩コートした。PBSTにて洗浄し抗原を除いた後、2% BSA-PBS 250μLにて1時間以上ブロッキングした。2% BSA-PBSを除き、ここに調製した培養上清を加え37℃で1時間静置し抗体を結合させた。洗浄後、50 mM PBS(pH7.4)もしくは50 mM PBS(pH5.5)を加え37℃で30分間静置しインキュベートした。洗浄後、2% BSA-PBSにて希釈したHRP結合抗M13抗体(Amersham Parmacia Biotech)とTMB single solution(ZYMED)で検出し、硫酸の添加により反応を停止した後、450 nmの吸光度を測定した。
Evaluation by Phage ELISA The above single colonies were inoculated into 100 μL 2YT / 100 μg / mL ampicillin / 2% glucose / 12.5 μg / mL tetracycline and cultured overnight at 30 ° C. Inoculate this 2 μL into 300 μL 2YT / 100 μg / mL ampicillin / 2% glucose, incubate at 37 ° C for 4 hours, add helper phage (M13KO7) 9 x 10 8 pfu, and incubate at 37 ° C for 30 minutes, 37 ° C. Infection was carried out by stirring culture for 30 minutes. After this, the medium was exchanged with 2YT / 100 μg / mL ampicillin / 25 μg / mL kanamycin / 0.5
しかしながらこの磁気ビーズに固定化した抗原を用いたパンニングでは、強いpH依存的結合能を有するクローンは得られなかった。弱いながらpH依存的結合能が認められたクローンについて、特異的プライマーを用い、配列解析を行った。これらのクローンにおいて、高い確率でヒスチジンとなっていた箇所を表3に示した。 However, panning using the antigen immobilized on the magnetic beads did not give a clone having a strong pH-dependent binding ability. The clones, which were weak but showed pH-dependent binding ability, were sequence-analyzed using specific primers. Table 3 shows the locations of these clones that had a high probability of becoming histidine.
[表3] ファージライブラリー(磁気ビーズパンニング)により見出されたヒスチジン置換箇所
H50, H58, H61, H62, H63, H64, H65, H102
L24, L27, L28, L32, L53, L56, L90, L92, L94
[Table 3] Histidine substitution sites found by phage library (magnetic bead panning)
H50, H58, H61, H62, H63, H64, H65, H102
L24, L27, L28, L32, L53, L56, L90, L92, L94
カラムパンニングによるライブラリーからのpH依存的結合scFvの取得
一般的な磁気ビーズに固定化した抗原を用いたパンニングでは強いpH依存的結合能を有するクローンは得られなかった。磁気ビーズに固定化した抗原を用いたパンニングやプレートに固定化した抗原を用いたパンニングの場合は、磁気ビーズあるいはプレートから酸性条件下で解離したファージを全て回収するため、pH依存性が弱いクローンのファージであっても回収されてしまい、最終的に濃縮されるクローンに強いpH依存性を有するクローンが含まれる可能性が低いことが原因と考えられる。
Acquisition of pH-dependent binding scFv from the library by column panning Panning using an antigen immobilized on general magnetic beads did not give a clone having a strong pH-dependent binding ability. In the case of panning using an antigen immobilized on a magnetic bead or panning using an antigen immobilized on a plate, all the phages dissociated from the magnetic bead or the plate under acidic conditions are recovered, so that the clone has a weak pH dependence. It is considered that the cause is that even the phages of the above are recovered, and it is unlikely that the clone that is finally concentrated contains a clone having a strong pH dependence.
そこで、より厳しい条件でのパンニング方法として抗原を固定化したカラムを用いたパンニングを検討した(図5)。抗原を固定化したカラムを用いたパンニングを用いてpH依存的結合能を有するクローンを取得した報告はこれまでにない。抗原を固定化したカラムを用いたパンニングの場合、中性条件下で結合させたファージを酸性条件で溶出させる際、pH依存性が弱いクローンはカラム内で抗原に再結合することで溶出されにくく、pH依存性が強くカラム内の再結合が起こりにくいクローンが選択的にカラムから溶出されることが考えられる。また、磁気ビーズに固定化した抗原を用いたパンニングやプレートに固定化した抗原を用いたパンニングでは酸性条件下で解離したファージを"全て"回収することになるが、抗原を固定化したカラムを用いたパンニングではカラムに酸性条件の緩衝液を流すことで溶出を開始し"適切なフラクションのみ"を回収することで、強いpH依存的結合能を有するファージを選択的に回収することが可能と考えられる。 Therefore, as a panning method under stricter conditions, panning using an antigen-immobilized column was examined (Fig. 5). There has been no report of obtaining a clone having pH-dependent binding ability by using panning using a column on which an antigen is immobilized. In the case of panning using an antigen-immobilized column, when the phage bound under neutral conditions is eluted under acidic conditions, clones with weak pH dependence are less likely to be eluted by rebinding to the antigen in the column. It is conceivable that clones with strong pH dependence and less likely recombination in the column are selectively eluted from the column. In addition, panning using an antigen immobilized on magnetic beads or panning using an antigen immobilized on a plate results in "all" recovery of phages dissociated under acidic conditions, but a column in which the antigen is immobilized is used. In the panning used, elution is started by flowing a buffer solution under acidic conditions on the column, and by collecting "only appropriate fractions", it is possible to selectively collect phages with strong pH-dependent binding ability. Conceivable.
まず、抗原であるSR344を固定化したカラムを作製した。200μL Streptavidin Sepharose(GE Healthcare)を1 mL PBSにてwashを行った後、500μL PBSに懸濁し、ビオチン標識SR344 400 pmolと室温で1時間接触させた。その後、空カラム(Amersham Pharmcia Biotech)へ上記のsepharoseを充填し、約3 mLのPBSによりカラムの洗浄を行った。0.5% BSA-PBS(pH7.4)により上記のPEG沈したlibrary phageを1/25に希釈し0.45 nm filterを通した後、カラムに添加した。約6 mLのPBS(pH7.4)にて洗浄した後、50 mM MES-NaCl(pH5.5)を流し、低いpHにすると解離する抗体を溶出した。適切な溶出フラクションを回収し、回収したファージ溶液に、対数増殖期(OD600 0.4-0.5)XL1-Blue 10 mLに添加、37℃, 30分間静置することで感染させた。 First, a column on which SR344, which is an antigen, was immobilized was prepared. 200 μL Streptavidin Sepharose (GE Healthcare) was washed with 1 mL PBS, suspended in 500 μL PBS, and contacted with biotin-labeled SR344 400 pmol at room temperature for 1 hour. Then, an empty column (Amersham Pharmcia Biotech) was filled with the above sepharose, and the column was washed with about 3 mL of PBS. The above PEG-precipitated library phage was diluted 1/25 with 0.5% BSA-PBS (pH 7.4), passed through a 0.45 nm filter, and then added to the column. After washing with about 6 mL of PBS (pH 7.4), 50 mM MES-NaCl (pH 5.5) was flowed to elute the antibody that dissociates at a low pH. Appropriate elution fractions were collected, and the collected phage solution was added to 10 mL of XL1-Blue during the logarithmic growth phase (OD600 0.4-0.5) and allowed to stand at 37 ° C. for 30 minutes for infection.
感染させた大腸菌を、2YT/100μg/mLアンピシリン/2% glucoseの225 mm x 225 mmのプレートへプレーティングした。再度この大腸菌から培養を開始し、上記と同様にファージの培養を行い、パンニングを6回繰り返し行った。 Infected E. coli was plated on a 225 mm x 225 mm plate of 2YT / 100 μg / mL ampicillin / 2% glucose. Culturing was started from this Escherichia coli again, phages were cultured in the same manner as above, and panning was repeated 6 times.
ファージELISAによる評価
ファージELISAにより、得られたphageの評価をおこなった。pH依存性が強く認められたクローンについて、特異的プライマーを用い、配列解析を行った。その結果、WTと比較してpH依存的な結合が強く見られたクローンが複数得られた。図6に示すとおり、WTと比較してクローンCL5(H鎖CLH5、L鎖CLL5)(CLH5:アミノ酸配列 配列番号:5、CLL5:アミノ酸配列 配列番号:8)は特に強いpH依存的な結合が確認された。一般的な磁気ビーズに固定化した抗原を用いたパンニングでは取れなかった強いpH依存的結合を示す抗体が、抗原を固定化したカラムを用いたパンニングにより取得できることが分かり、pH依存的結合抗体をライブラリーから取得する方法としては抗原を固定化したカラムを用いたパンニングが非常に有効であることが分かった。pH依存的な結合が見られた複数のクローンのアミノ酸配列解析の結果、濃縮されたクローンにおいて高い確率でヒスチジンとなっていた箇所を表4に示した。
Evaluation by Phage ELISA The obtained phage was evaluated by phage ELISA. Sequence analysis was performed on clones with strong pH dependence using specific primers. As a result, a plurality of clones in which pH-dependent binding was strongly observed as compared with WT were obtained. As shown in FIG. 6, the clone CL5 (H chain CLH5, L chain CLL5) (CLH5: amino acid sequence SEQ ID NO: 5, CLL5: amino acid sequence SEQ ID NO: 8) has a particularly strong pH-dependent binding as compared with WT. confirmed. It was found that an antibody showing strong pH-dependent binding that could not be obtained by panning using an antigen immobilized on a general magnetic bead can be obtained by panning using a column on which an antigen is immobilized, and a pH-dependent binding antibody was obtained. It was found that panning using a column on which an antigen was immobilized was very effective as a method for obtaining from the library. As a result of amino acid sequence analysis of a plurality of clones in which pH-dependent binding was observed, Table 4 shows the locations where histidine was formed with high probability in the concentrated clones.
[表4] ファージライブラリー(カラムパンニング)によるヒスチジン置換箇所
H31, H50, H58, H62, H63, H65, H100b, H102
L24, L27, L28, L32, L53, L56, L90, L92, L94
[Table 4] Histidine substitution site by phage library (column panning)
H31, H50, H58, H62, H63, H65, H100b, H102
L24, L27, L28, L32, L53, L56, L90, L92, L94
〔実施例4〕ヒト化IL-6レセプター抗体のヒスチジン改変体の発現と精製
ヒト化IL-6レセプター抗体のヒスチジン改変抗体の発現ベクターの作製・発現・精製
ファージELISAにてpH依存性が強く認められたクローンについて、IgG化するために、VH、および、VLをそれぞれPCRによって増幅し、XhoI/NheI消化およびEcoRI消化により動物細胞発現用ベクターに挿入した。各DNA断片の塩基配列は、当業者公知の方法で決定した。H鎖としてCLH5、L鎖として実施例2で得られたL73を用いたCLH5/L73をIgGとして発現・精製した。発現・精製は実施例1に記載した方法で行った。
[Example 4] Expression and purification of a histidine variant of a humanized IL-6 receptor antibody
Preparation, expression, and purification of expression vector for histidine-modified antibody of humanized IL-6 receptor antibody For clones whose pH dependence was strongly observed by phage ELISA, VH and VL were each subjected to PCR for IgG conversion. It was amplified and inserted into an animal cell expression vector by XhoI / NheI digestion and EcoRI digestion. The base sequence of each DNA fragment was determined by a method known to those skilled in the art. CLH5 / L73 using CLH5 as the H chain and L73 obtained in Example 2 as the L chain was expressed and purified as IgG. Expression and purification were carried out by the method described in Example 1.
変異箇所の組み合わせにより、さらに高いpH依存性をもつ抗体作製を行った。ファージライブラリーでHisが濃縮された箇所、構造情報、などから、H鎖として実施例2で得られたH3pIのH32、H58、H62、H102をヒスチジンに置換し、さらにH95をバリンに、H99をイソロイシンに置換し、H170(配列番号:4)を作製した。改変体の作製は実施例1に記載した方法で行った。また、L鎖として実施例2で作成したL73の28番目のヒスチジンをアスパラギン酸に置換したL82(配列番号:7)を作製した。改変体の作製は実施例1に記載した方法で行った。実施例1に記載した方法で、H鎖としてH170、L鎖としてL82を用いたH170/L82をIgGとして発現・精製を行った。 Antibodies with even higher pH dependence were produced by combining the mutation sites. From the location where His was concentrated in the phage library, structural information, etc., H32, H58, H62, H102 of H3pI obtained in Example 2 as H chains were replaced with histidine, and H95 was replaced with valine and H99 was replaced with valine. It was replaced with isoleucine to prepare H170 (SEQ ID NO: 4). The modified product was prepared by the method described in Example 1. In addition, L82 (SEQ ID NO: 7) was prepared by substituting aspartic acid for the 28th histidine of L73 prepared in Example 2 as an L chain. The modified product was prepared by the method described in Example 1. H170 / L82 using H170 as the H chain and L82 as the L chain was expressed and purified as IgG by the method described in Example 1.
〔実施例5〕pH依存的結合抗体のIL-6R中和活性評価
IgG化したクローンのヒトIL-6レセプター中和活性評価
ヒト化PM1抗体(野生型:WT)、および、実施例2、4で作製したH3pI/L73、CLH5/L73、H170/L82の4種類についてIL-6レセプター中和活性を評価した。
[Example 5] Evaluation of IL-6R neutralization activity of pH-dependent binding antibody
Evaluation of human IL-6 receptor neutralization activity of IgG- ized clones Humanized PM1 antibody (wild type: WT) and 4 types of H3pI / L73, CLH5 / L73, and H170 / L82 prepared in Examples 2 and 4. The IL-6 receptor neutralizing activity was evaluated.
具体的にはIL-6/IL-6レセプター依存性増殖を示すBaF3/gp130を用いて、IL-6レセプター中和活性を評価した。BaF3/gp130を10% FBSを含むRPMI1640培地で3回洗浄した後に、5 x 104 cells/mLとなるように60 ng/mLのhuman interleukin-6(TORAY)、60 ng/mLの組換え可溶型ヒトIL-6レセプター(SR344)および10% FBSを含むRPMI1640培地に懸濁し、96 well-plate(CORNING)の各wellに50μLずつ分注した。次に、精製した抗体を10% FBSを含むRPMI1640に希釈して、各wellに50μLずつ混合した。37℃、5% CO2条件下で、3日間培養し、PBSで2倍に希釈したWST-8試薬(Cell Counting Kit-8、株式会社同仁化学研究所)を20μL/wellで加え、直後にSUNRISE CLASSIC(TECAN)を用いて450 nmの吸光度(参照波長620 nm)を測定した。2時間培養した後に、再度450 nmの吸光度(参照波長620 nm)を測定し、2時間の吸光度変化を指標にIL-6レセプター中和活性を評価した。その結果、図7に示すように、ヒト化PM1抗体(野生型:WT)と比較して、H3pI/L73、CLH5/L73、H170/L82は同等の生物学的中和活性を有することが示された。 Specifically, the IL-6 receptor neutralizing activity was evaluated using BaF3 / gp130, which exhibits IL-6 / IL-6 receptor-dependent proliferation. After washing BaF3 / gp130 three times in RPMI1640 medium containing 10% FBS, 60 ng / mL human interleukin-6 (TORAY), 60 ng / mL recombinantly available to 5 x 10 4 cells / mL It was suspended in RPMI1640 medium containing dissolved human IL-6 receptor (SR344) and 10% FBS, and 50 μL was dispensed into each well of 96 well-plate (CORNING). The purified antibody was then diluted to RPMI 1640 with 10% FBS and mixed 50 μL into each well. Incubate for 3 days under 37 ° C. and 5% CO 2 conditions, add WST-8 reagent (Cell Counting Kit-8, Dojin Chemical Laboratory Co., Ltd.) diluted 2-fold with PBS at 20 μL / well, and immediately after Absorbance at 450 nm (reference wavelength 620 nm) was measured using SUNRISE CLASSIC (TECAN). After culturing for 2 hours, the absorbance at 450 nm (reference wavelength 620 nm) was measured again, and the IL-6 receptor neutralizing activity was evaluated using the change in absorbance for 2 hours as an index. As a result, as shown in FIG. 7, it was shown that H3pI / L73, CLH5 / L73, and H170 / L82 have equivalent biological neutralizing activity as compared with the humanized PM1 antibody (wild type: WT). Was done.
〔実施例6〕pH依存的結合抗体のBiacore解析
pH依存的結合クローンの可溶型IL-6レセプターへの結合解析
ヒト化PM1抗体(野生型:WT)、および、実施例2、4で作製したH3pI/L73、CLH5/L73、H170/L82の4種類について、Biacore T100(GE Healthcare)を用いてpH5.8とpH7.4における抗原抗体反応の速度論的解析を実施した(バッファーは10 mM MES pH7.4あるいはpH5.8, 150 mM NaCl, 0.05% Tween20)。アミンカップリング法によりrecomb-proteinA/G(Pierce)を固定化したセンサーチップ上に種々の抗体を結合させ、そこにアナライトとして9.8-400 nMの濃度に調製したSR344を注入した。pH依存的結合クローンのSR344への結合および解離をリアルタイムに観測した(図8および図9)。測定は全て37℃で実施した。Biacore T100 Evaluation Software(GE Healthcare)を用い、結合速度定数 ka(1/Ms)、および解離速度定数 kd(1/s)を算出し、その値をもとに解離定数 KD (M) を算出した(表5)。さらにそれぞれについてpH5.8とpH7.4のaffinity比を算出し、pH依存性結合を評価した。測定は全て37℃で実施した。
[Example 6] Biacore analysis of pH-dependent binding antibody
Binding analysis of pH-dependent binding clones to soluble IL-6 receptor Humanized PM1 antibody (wild type: WT) and H3pI / L73, CLH5 / L73, H170 / L82 prepared in Examples 2 and 4 Kinetic analysis of antigen-antibody reaction at pH 5.8 and pH 7.4 was performed using Biacore T100 (GE Healthcare) for 4 types (buffer is 10 mM MES pH 7.4 or pH 5.8, 150 mM NaCl, 0.05% Tween 20). Various antibodies were bound onto a sensor chip on which recomb-protein A / G (Pierce) was immobilized by the amine coupling method, and SR344 prepared at a concentration of 9.8-400 nM was injected into the sensor chip. Binding and dissociation of pH-dependent binding clones to SR344 was observed in real time (FIGS. 8 and 9). All measurements were performed at 37 ° C. Using Biacore T100 Evaluation Software (GE Healthcare), calculate the binding rate constant k a (1 / Ms) and the dissociation rate constant k d (1 / s), and calculate the dissociation constant KD (M) based on the values. Calculated (Table 5). Furthermore, the affinity ratios of pH 5.8 and pH 7.4 were calculated for each, and the pH-dependent binding was evaluated. All measurements were performed at 37 ° C.
それぞれについてpH5.8とpH7.4のaffinity比を算出した結果、SR344に対するH3pI/L73,H170/L82,CLH5/L73のpH依存性結合(affinity)はそれぞれ41倍,394倍,66倍であり、いずれのクローンもWTと比較して15倍以上の高いpH依存的結合を示した。 As a result of calculating the affinity ratios of pH 5.8 and pH 7.4 for each, the pH-dependent affinities of H3pI / L73, H170 / L82, and CLH5 / L73 with respect to SR344 were 41 times, 394 times, and 66 times, respectively. Both clones showed a pH-dependent binding that was more than 15 times higher than that of WT.
これまでに血漿中のpHであるpH7.4においては抗原に強く結合し、エンドソーム内のpHであるpH5.5〜pH6.0において抗原に弱く結合する抗IL-6レセプター抗体は報告されていない。本検討において、WTのヒト化IL-6レセプター抗体と同等の生物学的中和活性およびpH7.4でのaffinityを維持したまま、pH5.8でのaffinityのみを特異的に10倍以上低下させた抗体が得られた。 To date, no anti-IL-6 receptor antibody has been reported that binds strongly to the antigen at the plasma pH of pH 7.4 and weakly binds to the antigen at the endosome pH of pH 5.5 to pH 6.0. .. In this study, only the affinity at pH 5.8 was specifically reduced by 10-fold or more while maintaining the same biological neutralization activity and affinity at pH 7.4 as the humanized IL-6 receptor antibody of WT. Antibodies were obtained.
[表5] SR344に対するpH依存的結合クローンの可溶型IL-6レセプターへの結合比較
[Table 5] Comparison of binding of pH-dependent binding clones to SR344 to soluble IL-6 receptor
pH依存的結合クローンの膜型IL-6レセプターへの結合解析
作製した上記pH依存的結合クローンについて、Biacore T100(GE Healthcare)を用いてpH5.8, pH7.4における膜型IL-6レセプターへの抗原抗体反応を観測した。センサーチップ上に固定化したIL-6レセプターへの結合を評価することで、膜型IL-6レセプターへの結合を評価した。SR344を当業者公知の方法に従ってビオチン化し、ストレプトアビジンとビオチンの親和性を利用し、ストレプトアビジンを介してビオチン化SR344をセンサーチップ上に固定化した。測定は全て37℃で実施し、移動相のバッファーは10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20とし、そこにpH依存的結合クローンをpH7.4の条件下で注入してSR344と結合させたのち(注入サンプルのバッファーは10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20)、移動相のpHである5.8で各クローンのpH依存的な解離を観測した(図10)。
Binding analysis of pH-dependent binding clones to membrane-type IL-6 receptor The prepared pH-dependent binding clones were subjected to membrane-type IL-6 receptor at pH 5.8 and pH 7.4 using Biacore T100 (GE Healthcare). Antigen-antibody reaction was observed. The binding to the membrane-type IL-6 receptor was evaluated by evaluating the binding to the IL-6 receptor immobilized on the sensor chip. SR344 was biotinylated according to a method known to those skilled in the art, and the biotinylated SR344 was immobilized on the sensor chip via streptavidin by utilizing the affinity between streptavidin and biotin. All measurements were performed at 37 ° C., the mobile phase buffer was 10 mM MES pH 5.8, 150 mM NaCl, 0.05
サンプル濃度を0.5μg/mLとし、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で結合させ、10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20で解離させたときのpH5.8における解離相のみBiacore T100 Evaluation Software(GE Healthcare)を用いフィッティングすることにより、pH5.8における解離速度(kd(1/s))を算出した。同様にまた、サンプル濃度を0.5μg/mLとし、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で結合させ、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で解離させたときのpH7.4における解離相のみBiacore T100 Evaluation Software(GE Healthcare)を用いフィッティングすることにより、pH7.4における解離速度定数(kd(1/s))を算出した。各クローンのpH依存的な解離速度定数を表6に示した。 The sample concentration was 0.5 μg / mL, and the pH was 5.8 when bound with 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20 and dissociated with 10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20. The dissociation rate (k d (1 / s)) at pH 5.8 was calculated by fitting only the dissociation phase in 1 using Biacore T100 Evaluation Software (GE Healthcare). Similarly, when the sample concentration was 0.5 μg / mL, it was bound at 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20 and dissociated at 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20. The dissociation rate constant (k d (1 / s)) at pH 7.4 was calculated by fitting only the dissociation phase at pH 7.4 using Biacore T100 Evaluation Software (GE Healthcare). The pH-dependent dissociation rate constants for each clone are shown in Table 6.
[表6] SR344に対するpH依存的結合クローンの膜型IL-6レセプターからの解離速度定数比較
[Table 6] Comparison of dissociation rate constants from membrane-type IL-6 receptor of pH-dependent binding clones for SR344
解離度のpH依存性が大きい順にH3pI/L73,CLH5/L73,H170/L82であり、いずれのクローンもWTよりも高いpH依存性的な膜型IL-6レセプターからの解離を示した。しかし、pH依存的結合・解離の順位は可溶型IL-6レセプターと膜型IL-6レセプターで異なった。可溶型IL-6レセプターへの結合解析において最も高いpH依存性結合を示したH170/L82は、膜型IL-6レセプターへの結合解析においては最も低いpH依存性結合を示すことが明らかとなった。一般に、可溶型の抗原に対してIgG分子は1価(affinity)で結合するのに対して、膜型の抗原に対しては2価(avidity)で結合することが知られている。このような可溶型抗原と膜型抗原では結合様式の違いがH170/L82のpH依存的結合に影響したと考えられた。 H3pI / L73, CLH5 / L73, and H170 / L82 were in descending order of the degree of dissociation depending on pH, and all clones showed higher pH-dependent dissociation from the membrane-type IL-6 receptor than WT. However, the order of pH-dependent binding and dissociation was different between the soluble IL-6 receptor and the membrane IL-6 receptor. It was revealed that H170 / L82, which showed the highest pH-dependent binding in the binding analysis to the soluble IL-6 receptor, showed the lowest pH-dependent binding in the binding analysis to the membrane-type IL-6 receptor. became. In general, it is known that an IgG molecule binds to a soluble antigen with a monovalent (affinity), whereas it binds to a membrane-type antigen with avidity. It was considered that the difference in the binding mode between the soluble antigen and the membrane antigen affected the pH-dependent binding of H170 / L82.
〔実施例7〕pH依存的結合抗体による抗原への複数回結合の確認
実施例2で記したように、pH依存的結合抗体は抗原に複数回結合することが可能になると考えられる。すなわち、抗原が結合したpH依存的結合抗体は非特異的にエンドソーム内に取り込まれるが、エンドソーム内の酸性条件下において可溶型抗原から解離する。抗体はFcRnに結合することによって再び血漿中に戻り、血漿中に戻った抗体には抗原が結合していないことから、再び新たな抗原に結合することが可能である。これを繰り返すことによって、pH依存的結合抗体は抗原に複数回結合することが可能である。しかしながらpH依存的結合を有さないIgG抗体は、エンドソームの酸性条件下で全ての抗原が抗体から解離することは無いため、FcRnにより血漿中に戻った抗体は抗原を結合したままであり、再び新たな抗原に結合することは出来ない。そのため、ほとんどの場合1分子のIgG抗体は2つの抗原しか中和することが出来ない(2価で結合した場合)。
[Example 7] Confirmation of multiple binding to the antigen by the pH-dependent binding antibody As described in Example 2, it is considered that the pH-dependent binding antibody can bind to the antigen multiple times. That is, the pH-dependent binding antibody to which the antigen is bound is non-specifically incorporated into the endosome, but dissociates from the soluble antigen under acidic conditions in the endosome. The antibody returns to plasma by binding to FcRn, and since the antigen is not bound to the antibody returned to plasma, it is possible to bind to a new antigen again. By repeating this, the pH-dependent binding antibody can bind to the antigen multiple times. However, in IgG antibodies that do not have pH-dependent binding, not all antigens dissociate from the antibodies under acidic endosome conditions, so the antibodies returned to plasma by FcRn remain bound to the antigens and again. It cannot bind to new antigens. Therefore, in most cases, one molecule of IgG antibody can neutralize only two antigens (when bound by divalent).
そこで、実施例2、4で作製したH3pI/L73、CLH5/L73、H170/L82の3種類のpH依存的結合抗体が、ヒト化PM1抗体(野生型:WT)と比較して、抗原であるSR344に複数回結合することが可能になっているかどうかの評価を行った。 Therefore, the three types of pH-dependent binding antibodies, H3pI / L73, CLH5 / L73, and H170 / L82 prepared in Examples 2 and 4, are antigens as compared with the humanized PM1 antibody (wild type: WT). We evaluated whether it was possible to combine with SR344 multiple times.
pH7.4で結合し、pH5.8で解離することで抗原に複数回結合可能であることをBiacore(GE Healthcare)によって評価した。アミンカップリング法によりrecomb-proteinA/G(Pierce)を固定化したセンサーチップに対して評価する抗体を結合させ、pH7.4の移動相を流した(工程1)。pH7.4に調整したSR344溶液をアナライトとして流し、pH7.4で抗体にSR344を結合させた(工程2)。このpH7.4での結合は血漿中での抗原への結合を模倣している。その後、pH5.8に調整したバッファーのみ(SR344を含有しない溶液)をアナライトとして流して抗体に結合した抗原を酸性条件下に暴露させた(工程3)。このpH5.8での解離はエンドソーム内での抗体抗原複合体の結合状態を模倣している。その後、再び工程2を行った。これはFcRnによって血漿中に戻った抗体が再び新しい抗原に結合することを模倣している。その後、再び工程2を行い、抗体抗原複合体を酸性条件下に暴露させた。このように"工程2→工程3"を37℃で複数回繰り返すことによって、抗体が血漿中からピノサイトーシスによってエンドソーム内に取り込まれFcRnによって血漿中に戻ることを繰り返している(Nat Rev Immunol. 2007 Sep;7(9):715-25)生体内の状態を模倣することが可能である。
It was evaluated by Biacore (GE Healthcare) that it can bind to the antigen multiple times by binding at pH 7.4 and dissociating at pH 5.8. An antibody to be evaluated was bound to a sensor chip on which recomb-protein A / G (Pierce) was immobilized by an amine coupling method, and a mobile phase having a pH of 7.4 was allowed to flow (step 1). The SR344 solution adjusted to pH 7.4 was flowed as an analyzer, and SR344 was bound to the antibody at pH 7.4 (step 2). This binding at pH 7.4 mimics binding to the antigen in plasma. Then, only the buffer adjusted to pH 5.8 (a solution containing no SR344) was flowed as an analyst to expose the antigen bound to the antibody under acidic conditions (step 3). This dissociation at pH 5.8 mimics the binding state of the antibody-antigen complex within endosomes. Then,
作製した上記pH依存的結合クローンについて、Biacore T100(GE Healthcare)を用いてpH5.8, pH7.4における抗原であるSR344に対する複数回結合能を解析した。具体的には以下の通り行った。測定は全て37℃で実施し、まずアミンカップリング法によりrecomb-proteinA/G(Pierce)を固定化したセンサーチップ上に、移動相のバッファーは10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20とし、上述のサンプルとなる抗体を結合させた(工程1)。そこにアナライトとして約40 nMの濃度に調製したSR344をpH7.4の条件下で3分間注入して(注入SR344のバッファーは10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20)結合させた(工程2)。その後、SR344の注入を停止しpH5.8の移動相を約70秒間流すことにより抗体/SR344複合体を酸性条件下に暴露した(工程3)。この結合(工程2)および酸性暴露(工程3)を1セットとし、これを連続的に10セット繰り返し行い、そのセンサーグラムをリアルタイムに観測し図11に示した。WTは工程3の酸性暴露時のSR344の解離が少ないため、次の工程2で新たに抗原に結合可能な抗体の割合は非常に少ない。それに対して、pH依存的結合クローン、その中でも特にH170/L82とCLH5/L73は、工程3の酸性暴露時の解離が極めて大きく、結合しているSR344のほとんどが解離することから、次の工程2でほとんどの抗体が新たな抗原に結合可能であることが分かった。H170/L82とCLH5/L73は結合(工程2)と酸性暴露(工程3)を10セット繰り返しても、毎セットほとんどの抗体が新たな抗原に結合可能であることが分かった。
Biacore T100 (GE Healthcare) was used to analyze the multiple binding ability of the prepared pH-dependent binding clone to SR344, which is an antigen at pH 5.8 and pH 7.4. Specifically, the procedure was as follows. All measurements were performed at 37 ° C. First, the mobile phase buffer was 10 mM MES pH 5.8, 150 mM NaCl, 0.05% on a sensor chip on which recomb-protein A / G (Pierce) was immobilized by the amine coupling method. It was designated as Tween20, and the above-mentioned sample antibody was bound (step 1). SR344 prepared as an analyzer at a concentration of about 40 nM was injected therein for 3 minutes under the condition of pH 7.4 (the buffer of the injected SR344 was 10 mM MES pH 7.4, 150 mM NaCl, 0.05% Tween 20) and bound. (Step 2). Then, the injection of SR344 was stopped and the mobile phase of pH 5.8 was allowed to flow for about 70 seconds to expose the antibody / SR344 complex under acidic conditions (step 3). This binding (step 2) and acidic exposure (step 3) were set as one set, and this was continuously repeated for 10 sets, and the sensorgram was observed in real time and shown in FIG. Since WT has less dissociation of SR344 during acidic exposure in
得られたセンサーグラムを用いて、Biacore T100 Evaluation Software(Biacore)を用い、各サンプルの1セットごとのSR344結合量を算出し、10セットの経時的な積算値を図12に示した。10セット目で得られた積算RU値が10回のサイクルの中で結合した総抗原量に相当する。WTと比較して、pH依存的結合クローン、その中でも特にH170/L82とCLH5/L73は、結合した総抗原量が最も多く、WTと比較して4倍量程度の抗原に繰り返し結合することが可能であることが示された。これより、WTに対してpH依存的な結合を付与することによって、繰り返し抗原に結合し、複数の抗原を中和することが可能になることが明らかとなった。 Using the obtained sensorgrams, Biacore T100 Evaluation Software (Biacore) was used to calculate the SR344 binding amount for each set of each sample, and the cumulative values of 10 sets over time are shown in FIG. The integrated RU value obtained in the 10th set corresponds to the total amount of antigen bound in 10 cycles. Compared to WT, pH-dependent binding clones, especially H170 / L82 and CLH5 / L73, have the highest total amount of bound antigen, and can repeatedly bind to about 4 times the amount of antigen compared to WT. It was shown to be possible. From this, it was clarified that by imparting a pH-dependent bond to WT, it is possible to repeatedly bind to an antigen and neutralize a plurality of antigens.
〔実施例8〕pH依存的結合抗体のヒトIL-6レセプタートランスジェニックマウスによるPK/PD試験
IL-6レセプターは生体内に可溶型IL-6レセプターおよび膜型IL-6レセプターの両方の形で存在する(Nat Clin Pract Rheumatol. 2006 Nov;2(11):619-26)。抗IL-6レセプター抗体は可溶型IL-6レセプターおよび膜型IL-6レセプター両方に結合してそれらの生物学的な作用を中和する。抗IL-6レセプター抗体は膜型IL-6レセプターに結合後、膜型IL-6レセプターに結合したままインターナライゼーションによって細胞内のエンドソームに取り込まれ、その後、抗IL-6レセプター抗体は膜型IL-6レセプターに結合したままライソソームへ移行し一緒にライソソームにより分解されると考えられている。実施例6で評価したpH依存的結合抗IL-6レセプター抗体であるH3pI/L73、CLH5/L73、H170/L82が、エンドソーム内の酸性条件下で解離することでFcRnを介して血漿中へ戻ることが出来れば、血漿中に戻った抗体は再度抗原に結合することが可能になり、抗体1分子で複数の膜型IL-6レセプターを中和することが可能となる。エンドソーム内の酸性条件下で解離することでFcRnを介して血漿中へ戻ることが作製したpH依存的結合抗IL-6レセプター抗体で達成できているかどうかは、これらの抗体の薬物動態がWTと比較して改善しているかどうかを評価することで可能である。
[Example 8] PK / PD test of pH-dependent binding antibody using human IL-6 receptor transgenic mice
The IL-6 receptor exists in vivo in the form of both soluble IL-6 receptor and membrane IL-6 receptor (Nat Clin Pract Rheumatol. 2006 Nov; 2 (11): 619-26). Anti-IL-6 receptor antibodies bind to both soluble and membrane IL-6 receptors and neutralize their biological effects. After binding to the membrane-type IL-6 receptor, the anti-IL-6 receptor antibody is taken up by intracellular endosomes while binding to the membrane-type IL-6 receptor, and then the anti-IL-6 receptor antibody is incorporated into the membrane-type IL. -6 It is thought that it migrates to the lysosome while still bound to the receptor and is degraded together by the lysosome. The pH-dependent binding anti-IL-6 receptor antibodies evaluated in Example 6, H3pI / L73, CLH5 / L73, and H170 / L82, dissociate under acidic conditions in the endosomes and return to plasma via FcRn. If this is possible, the antibody returned to plasma can bind to the antigen again, and one molecule of the antibody can neutralize a plurality of membrane-type IL-6 receptors. Whether or not the pH-dependent binding anti-IL-6 receptor antibody produced to return to plasma via FcRn by dissociation under acidic conditions in endosomes can be achieved with the pharmacokinetics of these antibodies is WT. It is possible by comparing and evaluating whether or not there is improvement.
そこで、ヒト化PM1抗体(野生型:WT)、および、実施例2、4で作製したH3pI/L73、CLH5/L73、H170/L82の4種類について、ヒトIL-6レセプタートランスジェニックマウス(hIL-6R tg マウス、Proc Natl Acad Sci U S A. 1995 May 23;92(11):4862-6)における薬物動態を評価した。WTおよびH3pI/L73、CLH5/L73、H170/L82をhIL-6R tgマウスに25 mg/kgで静脈内に単回投与し、投与前、および、経時的に採血した。採取した血液は直ちに4℃、15,000 rpmで15分間遠心分離し、血漿を得た。分離した血漿は、測定を実施するまで-20℃以下に設定された冷凍庫に保存した。 Therefore, human IL-6 receptor transgenic mice (hIL-) were used for humanized PM1 antibody (wild type: WT) and four types of H3pI / L73, CLH5 / L73, and H170 / L82 prepared in Examples 2 and 4. The pharmacokinetics of 6R tg mice, Proc Natl Acad Sci US A. 1995 May 23; 92 (11): 4862-6) was evaluated. WT and H3pI / L73, CLH5 / L73, and H170 / L82 were intravenously administered to hIL-6R tg mice at a single dose of 25 mg / kg, and blood was collected before and over time. The collected blood was immediately centrifuged at 4 ° C. and 15,000 rpm for 15 minutes to obtain plasma. The separated plasma was stored in a freezer set at -20 ° C or lower until the measurement was performed.
マウス血漿中濃度測定はELISA法にて測定した。血漿中濃度として6.4、3.2、1.6、0.8、0.4、0.2、0.1μg/mLの検量線試料を調整した。検量線試料およびマウス血漿測定試料をAnti-human IgG(γ-chain specific) F(ab')2(Sigma社製)で固相化したイムノプレート(Nunc-Immuno Plate,MaxiSorp(Nalge nunc International社製))に分注し、室温で1時間静置後、Goat Anti-Human IgG-BIOT(Southern Biotechnology Associates社製)およびStreptavidin-alkaline phosphatase conjugate(Roche Diagnostics社製)を順次反応させ、BluePhos Microwell Phosphatase Substrates System(Kirkegaard & Perry Laboratories社製)を基質として用い発色反応を行い、マイクロプレートリーダーにて650 nmの吸光度を測定した。マウス血漿中濃度は検量線の吸光度から解析ソフトウェアSOFTmax PRO(Molecular Devices社製)を用いて算出した。WTおよびH3pI/L73、CLH5/L73、H170/L82の血漿中濃度推移を図13に示した。 The mouse plasma concentration was measured by the ELISA method. Calibration curve samples with plasma concentrations of 6.4, 3.2, 1.6, 0.8, 0.4, 0.2, and 0.1 μg / mL were prepared. Immunoplate (Nunc-Immuno Plate, MaxiSorp (Nalge nunc International)) in which the calibration line sample and the mouse plasma measurement sample were immobilized with Anti-human IgG (γ-chain specific) F (ab') 2 (manufactured by Sigma). )), After allowing to stand at room temperature for 1 hour, Goat Anti-Human IgG-BIOT (manufactured by Southern Biotechnology Associates) and Streptavidin-alkaline phosphatase conjugate (manufactured by Roche Diagnostics) are sequentially reacted, and BluePhos Microwell Phosphatase Substrates A color reaction was carried out using System (manufactured by Kirkegaard & Perry Laboratories) as a substrate, and the absorbance at 650 nm was measured with a microplate reader. The mouse plasma concentration was calculated from the absorbance of the calibration curve using the analysis software SOFTmax PRO (manufactured by Molecular Devices). The changes in plasma concentrations of WT, H3pI / L73, CLH5 / L73, and H170 / L82 are shown in FIG.
WTと比較してH3pI/L73、CLH5/L73、H170/L82いずれも薬物動態が改善した。中でもH3pI/L73およびCLH5/L73は薬物動態が大幅に改善した。膜型IL-6レセプターに結合した天然型抗IL-6レセプター抗体(WT)はインターナライゼーションによって細胞内のエンドソームに取り込まれ、抗原に結合したままライソソームに移行し分解されるため血漿中滞留性が短い。それに対してpH依存的結合抗IL-6レセプター抗体において薬物動態が大幅に改善したことから、pH依存的結合抗IL-6レセプター抗体はエンドソーム内の酸性条件下おいて抗原である膜型IL-6レセプターから解離することでFcRnを介して再び血漿中に戻っていると考えられた。 Pharmacokinetics was improved in all of H3pI / L73, CLH5 / L73, and H170 / L82 compared with WT. Among them, H3pI / L73 and CLH5 / L73 had significantly improved pharmacokinetics. The natural anti-IL-6 receptor antibody (WT) bound to the membrane-type IL-6 receptor is taken up by intracellular endosomes by internalization, transferred to the lysosome while bound to the antigen, and decomposed, resulting in plasma retention. short. On the other hand, since the pharmacokinetics of the pH-dependent binding anti-IL-6 receptor antibody was significantly improved, the pH-dependent binding anti-IL-6 receptor antibody is a membrane-type IL- that is an antigen under acidic conditions in endosomes. It was considered that the dissociation from the 6 receptors returned to the plasma via FcRn.
WTと比較してH3pI/L73、CLH5/L73、H170/L82いずれも薬物動態が改善したが、H170/L82の血漿中滞留性延長効果がH3pI/L73、CLH5/L73と比較して小さかった。通常IgG分子は膜型抗原には2価で結合すると考えられることから、抗IL-6レセプター抗体も膜型IL-6レセプターには2価(avidity)で結合してその後インターナライズされると考えられる。実施例6で示したように、Biacoreによる解析においてH170/L82は、可溶型IL-6レセプターへの結合の際はpH5.8において速やかにIL-6レセプターから解離する(図9)が、膜型IL-6レセプターへの結合の際はpH5.8においてIL-6レセプターからの解離速度が非常に遅い(図10)ことが分かっている。これよりH170/L82の血漿中滞留性延長効果が小さかったのは、膜型IL-6レセプターへの結合の際のpH5.8での解離が遅かったため、インターナライズされた後にエンドソーム内で十分に解離することが出来なかったためと考えられる。すなわち、膜型抗原に対して、1つのIgG分子が複数の膜型抗原を中和するためには、1価での結合(affinity)でのpH依存性よりも、2価での結合(avidity)からの解離のpH依存性のほうが重要であることが分かった。 The pharmacokinetics of H3pI / L73, CLH5 / L73, and H170 / L82 were all improved compared to WT, but the plasma retention prolonging effect of H170 / L82 was smaller than that of H3pI / L73 and CLH5 / L73. Since IgG molecules are usually considered to bind to membrane-type antigens in a divalent manner, anti-IL-6 receptor antibodies are also considered to bind to membrane-type IL-6 receptors in avidity and then internalized. Be done. As shown in Example 6, in the analysis by Biacore, H170 / L82 rapidly dissociates from the IL-6 receptor at pH 5.8 upon binding to the soluble IL-6 receptor (FIG. 9). It is known that the dissociation rate from the IL-6 receptor is very slow at pH 5.8 when binding to the membrane-type IL-6 receptor (Fig. 10). The reason why the plasma retention-prolonging effect of H170 / L82 was smaller than this was that the dissociation at pH 5.8 during binding to the membrane-type IL-6 receptor was slow, so that it was sufficiently in endosomes after internalization. It is probable that it could not be dissociated. That is, in order for one IgG molecule to neutralize a plurality of membrane-type antigens with respect to a membrane-type antigen, bivalent avidity rather than pH dependence of monovalent binding (affinity). It was found that the pH dependence of dissociation from) is more important.
〔実施例9〕pH依存的結合抗体のカニクイザルによるPK/PD試験
実施例8において、pH依存的結合抗IL-6レセプター抗体において薬物動態が大幅に改善したことから、pH依存的結合抗IL-6レセプター抗体はエンドソーム内の酸性条件下において抗原である膜型IL-6レセプターから解離することでFcRnを介して再び血漿中に戻っていると考えられた。再び血漿中に戻った抗体が再度膜型IL-6レセプターに結合することができれば、天然型抗IL-6レセプター抗体と比較して、pH依存的結合抗IL-6レセプター抗体は同じ投与量でより長く抗原である膜型IL-6レセプターの中和が持続すると考えられる。また、IL-6レセプターには可溶型IL-6レセプターも存在することから、可溶型IL-6レセプターの中和に関しても、同じ投与量でより長く中和が持続することが考えられる。
[Example 9] PK / PD test of pH-dependent binding antibody using cynomolgus monkey In Example 8, the pharmacokinetics of the pH-dependent binding anti-IL-6 receptor antibody was significantly improved. Therefore, pH-dependent binding anti-IL- It was considered that the 6-receptor antibody returned to plasma again via FcRn by dissociating from the membrane-type IL-6 receptor, which is an antigen, under acidic conditions in endosomes. If the antibody returned to plasma can bind to the membrane-type IL-6 receptor again, the pH-dependent binding anti-IL-6 receptor antibody will be at the same dose as compared to the native anti-IL-6 receptor antibody. It is considered that the neutralization of the membrane-type IL-6 receptor, which is an antigen, continues for a longer period of time. In addition, since the IL-6 receptor also contains a soluble IL-6 receptor, it is considered that the neutralization of the soluble IL-6 receptor can be sustained for a longer period of time at the same dose.
WTおよびH3pI/L73について、カニクイザルにおける薬物動態を評価した。WTおよびH3pI/L73をカニクイザルに1 mg/kgで静脈内に単回投与し、投与前および経時的に採血した。採取した血液は直ちに4℃、15,000 rpmで15分間遠心分離し、血漿を得た。分離した血漿は、測定を実施するまで-20℃以下に設定された冷凍庫に保存した。 The pharmacokinetics of WT and H3pI / L73 in cynomolgus monkeys were evaluated. A single intravenous dose of WT and H3pI / L73 was administered to cynomolgus monkeys at 1 mg / kg, and blood was collected before and over time. The collected blood was immediately centrifuged at 4 ° C. and 15,000 rpm for 15 minutes to obtain plasma. The separated plasma was stored in a freezer set at -20 ° C or lower until the measurement was performed.
カニクイザル血漿中濃度測定はELISA法にて測定した。まずAnti-Human IgG(γ-chain specific) F(ab')2 Fragment of Antibody(SIGMA社製)をNunc-Immuno Plate, MaxiSoup(Nalge nunc International社製)に分注し、4℃で1晩静置しAnti-Human IgG固相化プレートを作成した。血漿中濃度として3.2、1.6、0.8、0.4、0.2、0.1、0.05μg/mLの検量線試料と100倍以上希釈したカニクイザル血漿測定試料を調製し、これら検量線試料および血漿測定試料100μLに20 ng/mLのカニクイザルIL-6Rを200μL加え、室温で1時間静置した。その後Anti-Human IgG固相化プレートに分注しさらに室温で1時間静置した。その後Biotinylated Anti-human IL-6 R Antibody(R&D社製)を室温で1時間反応させ、さらにStreptavidin-PolyHRP80(Stereospecific Detection Technologies 社製)を室温で1時間反応させ、TMB One Component HRP Microwell Substrate(BioFX Laboratories社製)を基質として用い発色反応を行い、1N-Sulfuric acid(Showa Chemical社製)で反応停止後、マイクロプレートリーダーにて450 nmの吸光度を測定した。カニクイザル血漿中濃度は検量線の吸光度から解析ソフトウェアSOFTmax PRO(Molecular Devices社製)を用いて算出した。WTおよびH3pI/L73の静脈内投与後の血漿中濃度推移を図14に示した。その結果、カニクイザルにおいてもヒトIL-6レセプタートランスジェニックマウスと同様、WTと比較してH3pI/L73は大幅に薬物動態が改善した。pH依存的結合抗IL-6レセプター抗体であるH3pI/L73において薬物動態が大幅に改善したことから、H3pI/L73はエンドソーム内の酸性条件下において抗原である膜型IL-6レセプターから解離することでFcRnを介して再び血漿中に戻っていると考えられた。 The plasma concentration of cynomolgus monkey was measured by the ELISA method. First, Anti-Human IgG (γ-chain specific) F (ab') 2 Fragment of Antibody (manufactured by SIGMA) is dispensed into Nunc-Immuno Plate, MaxiSoup (manufactured by Nalge nunc International) and allowed to stand overnight at 4 ° C. An Anti-Human IgG-immobilized plate was prepared. Prepare a calibration curve sample having a plasma concentration of 3.2, 1.6, 0.8, 0.4, 0.2, 0.1, 0.05 μg / mL and a crab quill plasma measurement sample diluted 100-fold or more, and add 20 ng to these calibration curve samples and 100 μL of the plasma measurement sample. 200 μL of / mL crab quiz IL-6R was added, and the mixture was allowed to stand at room temperature for 1 hour. Then, it was dispensed into an Anti-Human IgG-immobilized plate and allowed to stand at room temperature for 1 hour. After that, the Biotinylated Anti-human IL-6 R Antibody (manufactured by R & D) was reacted at room temperature for 1 hour, and then Streptavidin-PolyHRP80 (manufactured by Stereospecific Detection Technologies) was reacted at room temperature for 1 hour, and TMB One Component HRP Microwell Substrate (BioFX) was reacted. A color reaction was carried out using Laboratories) as a substrate, the reaction was stopped with 1N-Sulfuric acid (Showa Chemical), and the absorbance at 450 nm was measured with a microplate reader. The plasma concentration of cynomolgus monkey was calculated from the absorbance of the calibration curve using the analysis software SOFTmax PRO (manufactured by Molecular Devices). The transition of plasma concentrations of WT and H3pI / L73 after intravenous administration is shown in FIG. As a result, the pharmacokinetics of H3pI / L73 was significantly improved in cynomolgus monkeys as in human IL-6 receptor transgenic mice as compared with WT. Since the pharmacokinetics of H3pI / L73, which is a pH-dependent binding anti-IL-6 receptor antibody, was significantly improved, H3pI / L73 dissociates from the membrane-type IL-6 receptor, which is an antigen, under acidic conditions in endosomes. It was considered that it returned to plasma again via FcRn.
WTおよびH3pI/L73の静脈内投与によって、カニクイザル膜型IL-6レセプターがどの程度中和されているかを評価するために、カニクイザルIL-6で誘導した血漿C反応性蛋白(CRP)への検体の影響を検討した。IL-6が膜型IL-6レセプターに結合するとCRPが分泌されるため、CRPは膜型IL-6レセプターの中和の指標となる。WTおよびH3pI/L73投与後3日目(day3)から10日目(day10)まで、1% 非働化カニクイザル血漿含有カニクイザルIL-6(実施例1で作製したcyno.IL-6) 5μg/kgを腰背部に連日皮下投与した。カニクイザルIL-6投与開始直前(day3)から投与後24時間間隔(day4〜day11)で伏在静脈より血液を採取して、血漿に分離した。各個体のCRP濃度はサイアスR CRP(関東化学株式会社)にて、自動分析装置(TBA-120FR、東芝メディカルシステムズ株式会社)を用いて測定した。WTおよびH3pI/L73のカニクイザルIL-6で誘導時のCRP濃度推移を図15に示した。その結果、WTと比較してH3pI/L73は大幅にCRP抑制の期間が大幅に延長した。このことから、pH依存的結合抗IL-6レセプター抗体であるH3pI/L73はエンドソーム内の酸性条件下において抗原である膜型IL-6レセプターから解離することでFcRnを介して再び血漿中に戻り、再度膜型IL-6レセプターに結合して中和することでWTよりも長時間CRPの産生を抑制していると考えられた。すなわちH3pI/L73は抗体1分子で複数回、膜型IL-6レセプターに結合し中和することが可能であることが示された。H3pI/L73はWTと比較して、CRPの産生を抑制している時間が延長していることから、H3pI/L73はWTよりも抗原である膜型IL-6レセプターが抗体によって結合されている時間が延長していることが示された。 Specimens to cynomolgus monkey IL-6-induced plasma C-reactive protein (CRP) to assess the extent to which cynomolgus monkey membrane IL-6 receptors are neutralized by intravenous administration of WT and H3pI / L73. The effect of was examined. CRP is an indicator of neutralization of the membrane-type IL-6 receptor because CRP is secreted when IL-6 binds to the membrane-type IL-6 receptor. From the 3rd day (day 3) to the 10th day (day 10) after administration of WT and H3pI / L73, 1% deactivated cynomolgus monkey plasma-containing cynomolgus monkey IL-6 (cyno.IL-6 prepared in Example 1) 5 μg / kg was administered. It was subcutaneously administered to the back of the waist every day. Blood was collected from the saphenous vein at intervals of 24 hours (day4 to day11) immediately before the start of administration of cynomolgus monkey IL-6 (day3) and separated into plasma. The CRP concentration of each individual was measured by Sias R CRP (Kanto Chemical Co., Inc.) using an automatic analyzer (TBA-120FR, Toshiba Medical Systems Corporation). The transition of CRP concentration at the time of induction in WT and H3pI / L73 cynomolgus monkey IL-6 is shown in FIG. As a result, H3pI / L73 significantly extended the period of CRP suppression compared to WT. From this, H3pI / L73, which is a pH-dependent binding anti-IL-6 receptor antibody, dissociates from the membrane-type IL-6 receptor, which is an antigen, under acidic conditions in the endosome, and returns to plasma again via FcRn. It was considered that CRP production was suppressed for a longer time than WT by binding to the membrane-type IL-6 receptor again and neutralizing it. That is, it was shown that H3pI / L73 can bind to and neutralize the membrane-type IL-6 receptor multiple times with one antibody molecule. Since H3pI / L73 has a longer time to suppress CRP production than WT, H3pI / L73 has a membrane-type IL-6 receptor that is an antigen more bound than WT by an antibody. It was shown that the time was extended.
WTおよびH3pI/L73の静脈内投与によって、カニクイザル可溶型IL-6レセプターがどの程度中和されているかを評価するために、カニクイザル血漿中の非結合型のカニクイザル可溶型IL-6レセプター濃度を測定した。カニクイザルの血漿30μLを0.22μmのフィルターカップ(Millipore)において乾燥させた適量のrProtein A Sepharose Fast Flow(GE Healthcare)樹脂に添加することで血漿中に存在する全てのIgG型抗体(カニクイザルIgG、抗ヒトIL-6レセプター抗体および抗ヒトIL-6レセプター抗体-カニクイザル可溶型IL-6レセプター複合体)をProteinAに吸着させた。その後、高速遠心機でスピンダウンし、通過した溶液(以下、「パス溶液」)を回収した。パス溶液にはproteinAに結合した抗ヒトIL-6レセプター抗体-カニクイザル可溶型IL-6レセプター複合体は含まれないため、proteinAパス溶液中のカニクイザル可溶型IL-6レセプター濃度を測定することによって、非結合型の可溶型IL-6レセプター濃度を測定可能である。4000、2000、1000、500、250、125、62.5 pg/mLに調製したカニクイザルIL-6レセプター検量線試料および上述のProtein A処理した血漿サンプルにSULFO-TAG NHS Ester(Meso Scale Discovery社製)でルテニウム化したMonoclonal Anti-human IL-6R Antibody(R&D社製)とBiotinylated Anti-human IL-6 R Antibody(R&D社製)を混合し室温で1時間反応させた。その後SA coated standard MA2400 96well plate(Meso Scale Discovery社製)に分注した。さらに室温で1時間反応させ洗浄後、Read Buffer T(×4)(Meso Scale Discovery社製)を分注し、ただちにSECTOR Imager 2400(Meso Scale Discovery社製)で測定を行った。カニクイザルIL-6レセプター濃度は検量線のレスポンスから解析ソフトウェアSOFTmax PRO(Molecular Devices社製)を用いて算出した。WTおよびH3pI/L73の非結合型のカニクイザル可溶型IL-6レセプター濃度推移を図16に示した。その結果、WTと比較してH3pI/L73は大幅にカニクイザル可溶型IL-6レセプターの中和期間が大幅に延長した。このことから、pH依存的結合抗IL-6レセプター抗体であるH3pI/L73はエンドソーム内の酸性条件下において抗原である可溶型IL-6レセプターから解離し、FcRnを介して再び血漿中に戻り、再度可溶型IL-6レセプターに結合して中和していると考えられた。H3pI/L73はWTと比較して、非結合型のカニクイザル可溶型IL-6レセプターを抑制している時間が延長していることから、H3pI/L73はWTよりも抗原である可溶型IL-6レセプターが抗体によって結合されている時間が延長していることが示された。 Concentration of unbound cynomolgus monkey soluble IL-6 receptor in cynomolgus monkey plasma to assess how much cynomolgus monkey soluble IL-6 receptor is neutralized by intravenous administration of WT and H3pI / L73 Was measured. All IgG-type antibodies present in plasma by adding 30 μL of crab quill plasma to an appropriate amount of rProtein A Sepharose Fast Flow (GE Healthcare) resin dried in a 0.22 μm filter cup (Millipore) (crab quill IgG, anti-human) IL-6 receptor antibody and anti-human IL-6 receptor antibody-Crab quiz-soluble IL-6 receptor complex) were adsorbed on Protein A. Then, it was spun down with a high-speed centrifuge, and the passed solution (hereinafter, “pass solution”) was recovered. Since the pass solution does not contain the anti-human IL-6 receptor antibody-crab-soluble IL-6 receptor complex bound to protein A, the concentration of the crab-quizal-soluble IL-6 receptor in the protein A pass solution should be measured. Allows the concentration of unbound soluble IL-6 receptor to be measured. SULFO-TAG NHS Ester (manufactured by Meso Scale Discovery) on the crab quiz monkey IL-6 receptor calibration line sample prepared at 4000, 2000, 1000, 500, 250, 125, 62.5 pg / mL and the above-mentioned Protein A-treated plasma sample. Lutheniumized Monoclonal Anti-human IL-6R Antibody (manufactured by R & D) and Biotinylated Anti-human IL-6 R Antibody (manufactured by R & D) were mixed and reacted at room temperature for 1 hour. After that, it was dispensed into SA coated standard MA2400 96well plate (manufactured by Meso Scale Discovery). After further reacting at room temperature for 1 hour and washing, Read Buffer T (× 4) (manufactured by Meso Scale Discovery) was dispensed and immediately measured with SECTOR Imager 2400 (manufactured by Meso Scale Discovery). The cynomolgus monkey IL-6 receptor concentration was calculated from the response of the calibration curve using the analysis software SOFTmax PRO (manufactured by Molecular Devices). The changes in the concentration of unbound cynomolgus monkey-soluble IL-6 receptor of WT and H3pI / L73 are shown in FIG. As a result, H3pI / L73 significantly extended the neutralization period of the cynomolgus monkey-soluble IL-6 receptor compared to WT. From this, H3pI / L73, which is a pH-dependent binding anti-IL-6 receptor antibody, dissociates from the soluble IL-6 receptor, which is an antigen, under acidic conditions in endosomes, and returns to plasma again via FcRn. , It was considered that it bound to the soluble IL-6 receptor again and neutralized. Since H3pI / L73 suppresses the unbound cynomolgus monkey soluble IL-6 receptor for a longer period of time compared to WT, H3pI / L73 is a more antigenic soluble IL than WT. It was shown that the time that the -6 receptor was bound by the antibody was prolonged.
これらのことから、野生型抗IL-6レセプター抗体に対して、血漿中のpHであるpH7.4において強く抗原に結合し、エンドソーム内のpHであるpH5.8において抗原への結合を弱くしたpH依存的結合抗IL-6レセプター抗体は、抗体が血漿中から消失するまでの時間、および、生体内の可溶型IL-6レセプターおよび膜型IL-6レセプターが抗体によって結合されている時間が大幅に延長することが見出された。これにより、患者への投与量や投与頻度を減らすことが可能であり、結果として総投与量を減らすことが可能となる為、pH依存的結合抗IL-6レセプター抗体は、IL-6アンタゴニストとしての医薬品として特に優れていると考えられる。 Based on these findings, the wild-type anti-IL-6 receptor antibody strongly bound to the antigen at pH 7.4, which is the plasma pH, and weakly bound to the antigen at pH 5.8, which is the endosome pH. The pH-dependent binding anti-IL-6 receptor antibody is the time required for the antibody to disappear from the plasma and the time required for the soluble IL-6 receptor and the membrane-type IL-6 receptor to be bound by the antibody in vivo. Was found to be significantly extended. This makes it possible to reduce the dose and frequency of administration to the patient, and as a result, the total dose can be reduced. Therefore, the pH-dependent binding anti-IL-6 receptor antibody can be used as an IL-6 antagonist. It is considered to be particularly excellent as a drug for.
〔実施例10〕可変領域の最適化による膜型IL-6レセプターへのpH依存的結合の向上
可変領域H3pI/L73およびCLH5/L82の最適化
実施例9において、pH依存的結合能を有する抗体が優れた効果を発揮することが示されたことから、さらにpH依存的結合能を向上させるため、実施例3で得られたCLH5のCDR配列に変異を導入し、VH1-IgG1(配列番号:21)、VH2-IgG1(配列番号:22)を作製した。また、H3pIのフレームワーク配列とCDR配列に変異を導入し、改変H鎖としてVH3-IgG1(配列番号:23)、VH4-IgG1(配列番号:24)を作製した。L73、L82のCDR配列に変異を導入し、改変L鎖としてVL1-CK(配列番号:25)、VL2-CK(配列番号:26)、VL3-CK(配列番号:27)を作製した。具体的には、QuikChange Site-Directed Mutagenesis Kit(Stratagene)を用いて、添付説明書記載の方法で変異体を作製し、得られたプラスミド断片を哺乳動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。
[Example 10] Improvement of pH-dependent binding to membrane-type IL-6 receptor by optimizing variable region
Optimization of Variable Regions H3pI / L73 and CLH5 / L82 In Example 9, it was shown that an antibody having a pH-dependent binding ability exerts an excellent effect. Therefore, in order to further improve the pH-dependent binding ability. , A mutation was introduced into the CDR sequence of CLH5 obtained in Example 3 to prepare VH1-IgG1 (SEQ ID NO: 21) and VH2-IgG1 (SEQ ID NO: 22). In addition, mutations were introduced into the framework sequence and CDR sequence of H3pI to prepare VH3-IgG1 (SEQ ID NO: 23) and VH4-IgG1 (SEQ ID NO: 24) as modified H chains. Mutations were introduced into the CDR sequences of L73 and L82 to prepare VL1-CK (SEQ ID NO: 25), VL2-CK (SEQ ID NO: 26), and VL3-CK (SEQ ID NO: 27) as modified L chains. Specifically, using the QuikChange Site-Directed Mutagenesis Kit (Stratagene), a mutant was prepared by the method described in the attached manual, and the obtained plasmid fragment was inserted into a mammalian cell expression vector to insert the desired H chain. An expression vector and an L chain expression vector were prepared. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art.
H鎖としてVH2-IgG1(配列番号:22)、L鎖としてVL2-CK(配列番号:26)を用いたものをFv1-IgG1、H鎖としてVH1-IgG1(配列番号:21)、L鎖としてL82を用いたものをFv2-IgG1、H鎖としてVH4-IgG1(配列番号:24)、L鎖としてVL1-CK(配列番号:25)を用いたものをFv3-IgG1、H鎖としてVH3-IgG1(配列番号:23)、L鎖としてVL3-CK(配列番号:27)を用いたものをFv4-IgG1とした。これらのうちFv2-IgG1とFv4-IgG1の発現・精製を行った。発現・精製は実施例1に記載した方法で行った。 Fv1-IgG1 using VH2-IgG1 (SEQ ID NO: 22) as the H chain and VL2-CK (SEQ ID NO: 26) as the L chain, VH1-IgG1 (SEQ ID NO: 21) as the H chain, and L chain Fv2-IgG1 using L82, VH4-IgG1 as H chain (SEQ ID NO: 24), Fv3-IgG1 using VL1-CK (SEQ ID NO: 25) as L chain, VH3-IgG1 as H chain (SEQ ID NO: 23) and VL3-CK (SEQ ID NO: 27) as the L chain were used as Fv4-IgG1. Of these, Fv2-IgG1 and Fv4-IgG1 were expressed and purified. Expression and purification were carried out by the method described in Example 1.
pH依存的結合クローンの可溶型IL-6レセプターへの結合解析
ヒト化PM1抗体(野生型:WT)、および、実施例2および10で作製したWT、H3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1の4種類について、Biacore T100(GE Healthcare)を用いてpH7.4における抗原抗体反応の速度論的解析を実施した(バッファーは10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20)。アミンカップリング法によりanti-IgG γchain specific F(ab)2(Pierce)を固定化したセンサーチップ上に種々の抗体を結合させ、そこにアナライトとして9.8-40 nMの濃度に調製したSR344を注入した。pH依存的結合クローンのSR344への結合および解離をリアルタイムに観測した。測定は全て37℃で実施した。Biacore T100 Evaluation Software(GE Healthcare)を用い、結合速度定数 ka (1/Ms)、および解離速度定数 kd (1/s) を算出し、その値をもとに 解離定数 KD (M) を算出した(表7)。
Binding analysis of pH-dependent binding clones to soluble IL-6 receptor Humanized PM1 antibody (wild type: WT) and WT, H3pI / L73-IgG1, Fv2-IgG1, prepared in Examples 2 and 10. Kinetic analysis of antigen-antibody reaction at pH 7.4 was performed using Biacore T100 (GE Healthcare) for 4 types of Fv4-IgG1 (buffer is 10 mM MES pH 7.4, 150 mM NaCl, 0.05% Tween 20). .. Various antibodies were bound onto a sensor chip on which anti-IgG γchain specific F (ab) 2 (Pierce) was immobilized by the amine coupling method, and SR344 prepared at a concentration of 9.8-40 nM was injected into the sensor chip. did. The binding and dissociation of pH-dependent binding clones to SR344 was observed in real time. All measurements were performed at 37 ° C. Using Biacore T100 Evaluation Software (GE Healthcare), calculate the binding rate constant k a (1 / Ms) and the dissociation rate constant k d (1 / s), and then calculate the dissociation constant KD (M) based on the values. Calculated (Table 7).
[表7] SR344に対するpH依存的結合クローンの可溶型IL-6レセプターからの解離速度定数比較
[Table 7] Comparison of dissociation rate constants from soluble IL-6 receptor of pH-dependent binding clones to SR344
それぞれについてpH7.4のaffinityを算出した結果、SR344に対するWT、H3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1の解離定数(affinity、KD値)はそれぞれ2.7 nM,1.4 nM, 2.0 nM, 1.4 nMとほぼ同等の値であり、Fv2-IgG1、Fv4-IgG1は可溶型IL-6レセプターへの結合能はWTと同等以上であることが示された。 As a result of calculating the affinity of pH 7.4 for each, the dissociation constants (affinity, KD value) of WT, H3pI / L73-IgG1, Fv2-IgG1, and Fv4-IgG1 with respect to SR344 are 2.7 nM, 1.4 nM, 2.0 nM, 1.4, respectively. The values were almost the same as nM, and it was shown that Fv2-IgG1 and Fv4-IgG1 have the same or higher binding ability to the soluble IL-6 receptor as WT.
pH依存的結合クローンの膜型IL-6レセプターへの結合解析
作製したWT、H3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1の4種類について、Biacore T100(GE Healthcare)を用いてpH5.8, pH7.4における膜型IL-6レセプターへの抗原抗体反応を観測した。センサーチップ上に固定化したIL-6レセプターへの結合を評価することで、膜型IL-6レセプターへの結合を評価した。SR344を当業者公知の方法に従ってビオチン化し、ストレプトアビジンとビオチンの親和性を利用し、ストレプトアビジンを介してビオチン化SR344をセンサーチップ上に固定化した。測定は全て37℃で実施し、移動相のバッファーは10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20とし、そこにpH依存的結合クローンをpH7.4の条件下で注入してSR344と結合させたのち(注入サンプルのバッファーは10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20)、移動相のpHである5.8で各クローンのpH依存的な解離を観測した(図17)。
Binding analysis of pH-dependent binding clones to membrane-type IL-6 receptor pH 5.8 for the four types of WT, H3pI / L73-IgG1, Fv2-IgG1, and Fv4-IgG1 prepared using Biacore T100 (GE Healthcare). The antigen-antibody reaction to the membrane-type IL-6 receptor at pH 7.4 was observed. The binding to the membrane-type IL-6 receptor was evaluated by evaluating the binding to the IL-6 receptor immobilized on the sensor chip. SR344 was biotinylated according to a method known to those skilled in the art, and the biotinylated SR344 was immobilized on the sensor chip via streptavidin by utilizing the affinity between streptavidin and biotin. All measurements were performed at 37 ° C., the mobile phase buffer was 10 mM MES pH 5.8, 150 mM NaCl, 0.05
サンプル濃度を0.25μg/mLとし、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で結合させ、10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20で解離させたときのpH5.8における解離相のみBiacore T100 Evaluation Software(GE Healthcare)を用いフィッティングすることにより、pH5.8における解離速度定数(kd(1/s))を算出した。同様にまた、サンプル濃度を0.25μg/mLとし、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で結合させ、10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20で解離させたときのpH7.4における解離相のみBiacore T100 Evaluation Software(GE Healthcare)を用いフィッティングすることにより、pH7.4における解離速度定数(kd(1/s))を算出した。各クローンのpH依存的な解離速度定数を表8に示した。 The sample concentration was 0.25 μg / mL, and the pH was 5.8 when bound at 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20 and dissociated at 10 mM MES pH5.8, 150 mM NaCl, 0.05% Tween20. The dissociation rate constant (k d (1 / s)) at pH 5.8 was calculated by fitting only the dissociation phase in 1 using Biacore T100 Evaluation Software (GE Healthcare). Similarly, when the sample concentration was 0.25 μg / mL, it was bound at 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20 and dissociated at 10 mM MES pH7.4, 150 mM NaCl, 0.05% Tween20. The dissociation rate constant (k d (1 / s)) at pH 7.4 was calculated by fitting only the dissociation phase at pH 7.4 using Biacore T100 Evaluation Software (GE Healthcare). The pH-dependent dissociation rate constants of each clone are shown in Table 8.
[表8] SR344に対するpH依存的結合クローンの膜型IL-6レセプターからの解離速度定数比較
[Table 8] Comparison of dissociation rate constants from membrane-type IL-6 receptor of pH-dependent binding clones for SR344
それぞれについてpH依存性を算出した結果SR344に対するWT、H3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1の4種類の膜型IL-6レセプターへの結合のpH依存性はそれぞれ1.0倍, 2.59倍, 7.18倍, 5.56倍であり、Fv2-IgG1、Fv4-IgG1は、H3pI/L73-IgG1より高いpH依存的な膜型IL-6レセプターからの解離を示した。 As a result of calculating the pH dependence for each, the pH dependence of binding to the four types of membrane-type IL-6 receptors of WT, H3pI / L73-IgG1, Fv2-IgG1 and Fv4-IgG1 for SR344 was 1.0 times and 2.59 times, respectively. Fv2-IgG1 and Fv4-IgG1 showed higher pH-dependent dissociation from the membrane-type IL-6 receptor than H3pI / L73-IgG1, respectively, 7.18 times and 5.56 times.
以上より、Fv2-IgG1、Fv4-IgG1はWTと同等以上の可溶型IL-6レセプターへのaffinityを維持したままH3pI/L73-IgG1よりも強い膜型IL-6レセプターへのpH依存的結合を示すことが明らかとなった。 From the above, Fv2-IgG1 and Fv4-IgG1 have stronger pH-dependent binding to the membrane-type IL-6 receptor than H3pI / L73-IgG1 while maintaining the affinity for the soluble IL-6 receptor equal to or higher than that of WT. It became clear that
〔実施例11〕可変領域を最適化したpH依存的結合抗体のヒトIL-6レセプタートランスジェニックマウスによるPK/PD試験
実施例8で使用したヒトIL-6レセプタートランスジェニックマウスを用いて、実施例10で作製・評価したFv2-IgG1とFv4-IgG1およびWTとH3pI/L73-IgG1の薬物動態を評価した。WTおよびH3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1をhIL-6R tgマウスに25 mg/kgで静脈内に単回投与し、実施例8と同様に各抗体の血漿中濃度の測定を行った。WTおよびH3pI/L73-IgG1、Fv2-IgG1、Fv4-IgG1の血漿中濃度推移を図18に示した。
[Example 11] PK / PD test of pH-dependent binding antibody with optimized variable region using human IL-6 receptor transgenic mouse Example using the human IL-6 receptor transgenic mouse used in Example 8. The pharmacokinetics of Fv2-IgG1 and Fv4-IgG1 and WT and H3pI / L73-IgG1 prepared and evaluated in No. 10 were evaluated. WT and H3pI / L73-IgG1, Fv2-IgG1, and Fv4-IgG1 were intravenously administered to hIL-6R tg mice at a single dose of 25 mg / kg, and the plasma concentration of each antibody was measured in the same manner as in Example 8. went. The changes in plasma concentrations of WT and H3pI / L73-IgG1, Fv2-IgG1 and Fv4-IgG1 are shown in FIG.
実施例8と同様、WTと比較してH3pI/L73-IgG1の薬物動態は向上しており、さらにFv2-IgG1およびFv4-IgG1はH3pI/L73-IgG1よりもさらに薬物動態が向上した。実施例9においてカニクイザルで測定した非結合型IL-6レセプター濃度に関しても同様の方法で本試験のhIL-6R tgマウスにおいて測定したところ、Fv2-IgG1およびFv4-IgG1はH3pI/L73-IgG1よりも可溶型IL-6レセプターの中和期間の延長が確認された(data not shown)。実施例10で示したとおり、Fv2-IgG1およびFv4-IgG1はH3pI/L73-IgG1と比較して膜型IL-6レセプターへのpH依存的結合が向上していることから、膜型IL-6レセプターへのpH依存的結合を向上させることにより、H3pI/L73-IgG1よりさらに薬物動態および可溶型IL-6レセプターの中和期間を向上させることが可能であることが示された。 Similar to Example 8, the pharmacokinetics of H3pI / L73-IgG1 was improved as compared with WT, and the pharmacokinetics of Fv2-IgG1 and Fv4-IgG1 were further improved as compared with H3pI / L73-IgG1. The unbound IL-6 receptor concentration measured in Crab monkeys in Example 9 was also measured in the hIL-6R tg mice of this test by the same method. As a result, Fv2-IgG1 and Fv4-IgG1 were higher than H3pI / L73-IgG1. An extension of the neutralization period of the soluble IL-6 receptor was confirmed (data not shown). As shown in Example 10, Fv2-IgG1 and Fv4-IgG1 have improved pH-dependent binding to the membrane-type IL-6 receptor as compared with H3pI / L73-IgG1, and thus membrane-type IL-6. It was shown that by improving the pH-dependent binding to the receptor, it is possible to further improve the pharmacokinetics and the neutralization period of the soluble IL-6 receptor as compared with H3pI / L73-IgG1.
〔実施例12〕定常領域の最適化による膜型IL-6レセプターへのpH依存的結合の向上
Fv4-IgG1の定常領域の最適化
一般的に膜型抗原に対する結合は抗体の定常領域によって変化することが報告されている(J Immunol Methods. 1997 Jun 23;205(1):67-72.)。これまで作製したpH依存的結合抗体の定常領域はIgG1アイソタイプであった。そこで膜型IL-6レセプターへのpH依存的結合を向上させるために定常領域の最適化を検討した。
[Example 12] Improvement of pH-dependent binding to membrane-type IL-6 receptor by optimizing the constant region
Optimization of constant region of Fv4-IgG1 Generally, it has been reported that the binding to a membrane antigen depends on the constant region of the antibody (J Immunol Methods. 1997 Jun 23; 205 (1): 67-72.). .. The constant region of the pH-dependent binding antibody produced so far was the IgG1 isotype. Therefore, we investigated the optimization of the constant region in order to improve the pH-dependent binding to the membrane-type IL-6 receptor.
天然型の定常領域として定常領域IgG2(配列番号:28)に変異を導入して、定常領域IgG2ΔGK(配列番号:29)を作製した。定常領域IgG2ΔGKに対してさらに変異を導入し、定常領域M58(配列番号:30)を作製した。定常領域IgG2および定常領域M58に対してさらに変異を導入し、定常領域M71(配列番号:31)およびM73(配列番号:32)を作製した。 Mutations were introduced into constant region IgG2 (SEQ ID NO: 28) as a natural constant region to prepare constant region IgG2ΔGK (SEQ ID NO: 29). Further mutations were introduced into the constant region IgG2ΔGK to prepare constant region M58 (SEQ ID NO: 30). Further mutations were introduced into the constant region IgG2 and constant region M58 to prepare constant regions M71 (SEQ ID NO: 31) and M73 (SEQ ID NO: 32).
実施例10で作製したVH3-IgG1の定常領域をIgG2ΔGKに置換したVH3-IgG2ΔGK(配列番号:33)、定常領域をM58に置換したVH3-M58(配列番号:34)、定常領域をM73に置換したVH3-M73(配列番号:35)を作製した。具体的には、実施例10で使用しているVH3の定常領域部分をNheI/NotI消化とligationにより目的の定常領域に置換した発現ベクターを構築した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。 VH3-IgG2ΔGK (SEQ ID NO: 33) in which the constant region of VH3-IgG1 prepared in Example 10 was replaced with IgG2ΔGK, VH3-M58 (SEQ ID NO: 34) in which the constant region was replaced with M58, and the constant region was replaced with M73. VH3-M73 (SEQ ID NO: 35) was prepared. Specifically, an expression vector was constructed in which the constant region portion of VH3 used in Example 10 was replaced with the target constant region by NheI / NotI digestion and ligation. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art.
H鎖としてVH3-IgG2ΔGK(配列番号:33)、L鎖としてVL3-CK(配列番号:27)を用いたFv4-IgG2、H鎖としてVH3-M58(配列番号:34)、L鎖としてVL3-CK(配列番号:27)を用いたFv4-M58、H鎖としてVH3-M73(配列番号:35)、L鎖としてVL3-CK(配列番号:27)を用いたFv4-M73の発現・精製を行った。発現・精製は実施例1に記載した方法で行った。 Fv4-IgG2 using VH3-IgG2ΔGK (SEQ ID NO: 33) as the H chain, VL3-CK (SEQ ID NO: 27) as the L chain, VH3-M58 (SEQ ID NO: 34) as the H chain, and VL3- as the L chain. Expression and purification of Fv4-M58 using CK (SEQ ID NO: 27), VH3-M73 as H chain (SEQ ID NO: 35), and Fv4-M73 using VL3-CK (SEQ ID NO: 27) as L chain. went. Expression and purification were carried out by the method described in Example 1.
定常領域を最適化したFv4の可溶型IL-6レセプターへの結合解析
作製したFv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73およびWTに関して、実施例10と同様の方法でSR344への結合および解離をリアルタイムに観測した。同様に解析を行い、結合速度定数 ka (1/Ms)、および解離速度定数 kd (1/s) を算出し、その値をもとに解離定数 KD (M) を算出した(表9)。
Binding analysis of Fv4 to soluble IL-6 receptor with optimized constant region For the prepared Fv4-IgG1, Fv4-IgG2, Fv4-M58, Fv4-M73 and WT, to SR344 in the same manner as in Example 10. Bonding and dissociation were observed in real time. The same analysis was performed to calculate the binding rate constant k a (1 / Ms) and the dissociation rate constant k d (1 / s), and the dissociation constant KD (M) was calculated based on the values (Table 9). ).
[表9] SR344に対するpH依存的結合クローンの可溶型IL-6レセプターからの解離速度定数比較
[Table 9] Comparison of dissociation rate constants from soluble IL-6 receptor of pH-dependent binding clones for SR344
それぞれについてpH7.4のaffinityを算出した結果、SR344に対するFv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73の解離定数(affinity、KD値)はそれぞれ1.4 nM,1.3 nM, 1.4 nM, 1.4 nMとほぼ同等の値であり、SR344に対するpH依存的結合クローンの可溶型IL-6レセプターへの結合能は定常領域を改変しても変化しないことが示された。このことから、Fv1、Fv2、Fv3についても同様に定常領域を改変しても可溶型IL-6レセプターへの結合能は変化しないと考えられた。 As a result of calculating the affinity of pH 7.4 for each, the dissociation constants (affinity, KD value) of Fv4-IgG1, Fv4-IgG2, Fv4-M58, and Fv4-M73 with respect to SR344 are 1.4 nM, 1.3 nM, 1.4 nM, 1.4, respectively. It was almost the same value as nM, and it was shown that the binding ability of the pH-dependent binding clone to SR344 to the soluble IL-6 receptor did not change even if the constant region was modified. From this, it was considered that the binding ability of Fv1, Fv2, and Fv3 to the soluble IL-6 receptor did not change even if the constant region was modified in the same manner.
定常領域を最適化したFv4の膜型IL-6レセプターへの結合解析
作製したFv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73およびWTに関して、実施例10と同様の方法でBiacore T100(GE Healthcare)を用いてpH5.8, pH7.4における膜型IL-6レセプターへの抗原抗体反応を観測した。pH依存的結合クローンをpH7.4の条件下で注入してSR344と結合させたのちに、pH5.8の移動相で各クローンのpH依存的な解離を観測した結果を図19に示す。さらに実施例10と同様の方法で解析を行い、各クローンのpH依存的な解離速度を表10に示した。
Binding analysis of Fv4 to membrane-type IL-6 receptor optimized for constant region For the prepared Fv4-IgG1, Fv4-IgG2, Fv4-M58, Fv4-M73 and WT, Biacore T100 ( GE Healthcare) was used to observe the antigen-antibody reaction to the membrane-type IL-6 receptor at pH 5.8 and pH 7.4. FIG. 19 shows the results of observing the pH-dependent dissociation of each clone in the mobile phase of pH 5.8 after injecting the pH-dependent binding clone under the condition of pH 7.4 to bind to SR344. Further analysis was performed in the same manner as in Example 10, and the pH-dependent dissociation rates of each clone are shown in Table 10.
[表10] SR344に対するpH依存的結合クローンの膜型IL-6レセプターからの解離速度定数比較
[Table 10] Comparison of dissociation rate constants from membrane-type IL-6 receptor of pH-dependent binding clones for SR344
それぞれについてpH依存性を算出した結果SR344に対するFv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73のpH依存性はそれぞれ5.6倍, 17.0倍, 17.6倍, 10.1倍であり、Fv4-IgG2、Fv4-M58、Fv4-M73のいずれもFv4-IgG1より高いpH依存性的な膜型IL-6レセプターからの解離を示した。 As a result of calculating the pH dependence for each, the pH dependence of Fv4-IgG1, Fv4-IgG2, Fv4-M58, and Fv4-M73 for SR344 was 5.6 times, 17.0 times, 17.6 times, and 10.1 times, respectively, and Fv4-IgG2, Both Fv4-M58 and Fv4-M73 showed higher pH-dependent dissociation from the membrane-type IL-6 receptor than Fv4-IgG1.
Fv4の可変領域を用いた可溶型IL-6レセプターへの結合解析結果および膜型IL-6レセプターへの結合解析結果より、定常領域をIgG1からIgG2、M58およびM73に置換することにより可溶型IL-6レセプターへのaffinityを変化させることなく、膜型IL-6レセプターへのpH依存的結合のみを改善可能であることが見出された。また、Fv1、Fv2、Fv3についても同様であると考えられた。 From the results of binding analysis to the soluble IL-6 receptor and the results of binding analysis to the membrane-type IL-6 receptor using the variable region of Fv4, it is soluble by substituting IgG1 with IgG2, M58 and M73 for the constant region. It was found that only pH-dependent binding to the membrane IL-6 receptor could be improved without altering the affinity for the type IL-6 receptor. The same was considered for Fv1, Fv2, and Fv3.
〔実施例13〕定常領域を最適化したpH依存的結合抗体のヒトIL-6レセプタートランスジェニックマウスによるPK/PD試験
実施例8で使用したヒトIL-6レセプタートランスジェニックマウス(hIL-6R tgマウス)を用いて、実施例13で作成したFv4-IgG1、Fv4-IgG2、Fv4-M58の薬物動態を評価し、定常領域の及ぼす薬物動態への影響を検討した。WTおよびFv4-IgG1、Fv4-IgG2、Fv4-M58をhIL-6R tgマウスに25 mg/kgで静脈内に単回投与し、実施例8と同様に各抗体の血漿中濃度の測定を行った。WTおよびFv4-IgG1、Fv4-IgG2、Fv4-M58の血漿中濃度推移を図20に示した。
[Example 13] PK / PD test of pH-dependent binding antibody with optimized constant region using human IL-6 receptor transgenic mouse The human IL-6 receptor transgenic mouse (hIL-6R tg mouse) used in Example 8 ) Was used to evaluate the pharmacokinetics of Fv4-IgG1, Fv4-IgG2, and Fv4-M58 prepared in Example 13, and the effect of the constant region on the pharmacokinetics was examined. WT, Fv4-IgG1, Fv4-IgG2, and Fv4-M58 were intravenously administered to hIL-6R tg mice at a single dose of 25 mg / kg, and the plasma concentration of each antibody was measured in the same manner as in Example 8. .. The changes in plasma concentrations of WT, Fv4-IgG1, Fv4-IgG2, and Fv4-M58 are shown in FIG.
実施例11と同様、WTと比較してFv4-IgG1の薬物動態は向上しており、さらにFv4-IgG2、Fv4-M58はFv4-IgG1よりも薬物動態は向上した。実施例9においてカニクイザルで測定した非結合型IL-6レセプター濃度に関しても同様の方法で本試験のhIL-6R tgマウスにおいて測定したところ、Fv4-IgG2、Fv4-M58はFv4-IgG1よりも可溶型IL-6レセプターの中和期間の延長が確認された(data not shown)。実施例10で示したとおり、Fv4-IgG2、Fv4-M58はFv4-IgG1と比較して膜型IL-6レセプターへのpH依存的結合の向上していることから、定常領域をIgG1からIgG2あるいはM58に置換することにより膜型IL-6レセプターへのpH依存的結合を向上させ、薬物動態および可溶型IL-6レセプターの中和期間を向上させることが可能であることが示された。これより、Fv4のみならずFv1、Fv2、Fv3においても、定常領域をIgG1からIgG2あるいはM58に置換することにより、IgG1よりも薬物動態および可溶型IL-6レセプターの中和期間が向上すると考えられた。 Similar to Example 11, the pharmacokinetics of Fv4-IgG1 was improved as compared with WT, and the pharmacokinetics of Fv4-IgG2 and Fv4-M58 were further improved as compared with Fv4-IgG1. The unbound IL-6 receptor concentration measured in Crab monkey in Example 9 was also measured in the hIL-6R tg mice of this test by the same method. As a result, Fv4-IgG2 and Fv4-M58 were more soluble than Fv4-IgG1. Prolonged neutralization period of type IL-6 receptor was confirmed (data not shown). As shown in Example 10, since Fv4-IgG2 and Fv4-M58 have improved pH-dependent binding to the membrane-type IL-6 receptor as compared with Fv4-IgG1, the constant region is changed from IgG1 to IgG2 or It has been shown that replacement with M58 can improve pH-dependent binding to membrane-type IL-6 receptors and improve pharmacokinetics and neutralization period of soluble IL-6 receptors. From this, it is considered that the pharmacokinetics and the neutralization period of soluble IL-6 receptor are improved compared to IgG1 by substituting the constant region from IgG1 to IgG2 or M58 not only in Fv4 but also in Fv1, Fv2, and Fv3. Was done.
〔実施例14〕可変領域および定常領域を最適化したpH依存的結合抗体の作製
これまでと同様の方法を用い、VH2-IgG1の定常領域をM71, M73としたVH2-M71(配列番号:36)、VH2-M73(配列番号:37)、VH4-IgG1の定常領域をM71, M73としたVH4-M71(配列番号:38)、VH4-M73(配列番号:39)を作製した。
[Example 14] Preparation of pH-dependent binding antibody with optimized variable region and constant region VH2-M71 (SEQ ID NO: 36) in which the constant region of VH2-IgG1 was M71 and M73 using the same method as before. ), VH2-M73 (SEQ ID NO: 37), VH4-M71 (SEQ ID NO: 38) and VH4-M73 (SEQ ID NO: 39) in which the constant regions of VH4-IgG1 were M71 and M73 were prepared.
H鎖としてVH2-M71、L鎖としてVL2-CKを用いたFv1-M71、H鎖としてVH2-M73、L鎖としてVL2-CKを用いたFv1-M73、H鎖としてVH4-M71、L鎖としてVL1-CKを用いたFv3-M71、H鎖として VH4-M73、L鎖としてVL1-CKを用いたFv3-M73の発現・精製を行った。発現・精製は実施例1に記載した方法で行った。 Fv1-M71 using VH2-M71 as H chain, VL2-CK as L chain, VH2-M73 as H chain, Fv1-M73 using VL2-CK as L chain, VH4-M71 as H chain, as L chain Expression and purification of Fv3-M71 using VL1-CK, VH4-M73 as H chain, and Fv3-M73 using VL1-CK as L chain were performed. Expression and purification were carried out by the method described in Example 1.
可変領域および定常領域を最適化したpH依存的結合抗体の可溶型IL-6レセプターへの結合解析
ヒト化PM1抗体(野生型:WT)、および、これまでに作製したH3pI/L73-IgG1、Fv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M71、Fv3-M73、Fv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73の11種類について、実施例10と同様の方法でSR344への結合および解離をリアルタイムに観測した。同様に解析を行い、結合速度定数 ka (1/Ms) 、および解離速度定数 kd (1/s) を算出し、その値をもとに解離定数 KD (M) を算出した(表11)。
Binding analysis of pH-dependent binding antibody optimized for variable region and constant region to soluble IL-6 receptor Humanized PM1 antibody (wild type: WT) and H3pI / L73-IgG1 prepared so far, For 11 types of Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M71, Fv3-M73, Fv4-IgG1, Fv4-IgG2, Fv4-M58, and Fv4-M73, to SR344 in the same manner as in Example 10. Bonding and dissociation were observed in real time. The same analysis was performed to calculate the binding rate constant k a (1 / Ms) and the dissociation rate constant k d (1 / s), and the dissociation constant KD (M) was calculated based on the values (Table 11). ).
[表11] SR344に対するpH依存的結合クローンの可溶型IL-6レセプターからの解離速度定数比較
[Table 11] Comparison of dissociation rate constants from soluble IL-6 receptor of pH-dependent binding clones for SR344
得られた10種類のpH依存的結合クローンは全て可溶型IL-6レセプターに対して、WTと比較して同等以上の解離定数(affinity、KD値)を有していることが見出された。 It was found that all the obtained 10 types of pH-dependent binding clones had a dissociation constant (affinity, KD value) equal to or higher than that of WT for the soluble IL-6 receptor. It was.
可変領域および定常領域を最適化したpH依存的結合抗体の膜型IL-6レセプターへの結合解析
ヒト化PM1抗体(野生型:WT)、および、これまでに作製したH3pI/L73-IgG1、Fv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M71、Fv3-M73、Fv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73の11種類について、実施例10と同様の方法でBiacore T100(GE Healthcare)を用いてpH5.8, pH7.4における膜型IL-6レセプターへの抗原抗体反応を観測した。pH依存的結合クローンをpH7.4の条件下で注入してSR344と結合させたのちに、移動相のpHである5.8で各クローンのpH依存的な解離を観測した結果を図21に示した(Fv1-M71、Fv1-M73、Fv3-M71、Fv3-M73については図21、他は図17および19に示した)。さらに実施例10と同様の方法で解析を行い、全11種類のクローンについて、解離速度定数のpH依存性を表12に示した。
Binding analysis of pH-dependent binding antibody with optimized variable region and constant region to membrane-type IL-6 receptor Humanized PM1 antibody (wild type: WT), and H3pI / L73-IgG1, Fv1 prepared so far -For 11 types of M71, Fv1-M73, Fv2-IgG1, Fv3-M71, Fv3-M73, Fv4-IgG1, Fv4-IgG2, Fv4-M58, and Fv4-M73, Biacore T100 (in the same manner as in Example 10) GE Healthcare) was used to observe the antigen-antibody reaction to the membrane-type IL-6 receptor at pH 5.8 and pH 7.4. Figure 21 shows the results of observing pH-dependent dissociation of each clone at a mobile phase pH of 5.8 after injecting a pH-dependent binding clone under the condition of pH 7.4 to bind to SR344. (Fv1-M71, Fv1-M73, Fv3-M71, Fv3-M73 are shown in FIG. 21, others are shown in FIGS. 17 and 19). Further analysis was performed in the same manner as in Example 10, and the pH dependence of the dissociation rate constant was shown in Table 12 for all 11 types of clones.
[表12] SR344に対するpH依存的結合クローンの膜型IL-6レセプターからの解離速度定数のpH依存性
[Table 12] pH-dependent binding to SR344 pH-dependent dissociation rate constant from membrane-type IL-6 receptor of clones
得られた10種類のpH依存的結合クローンは膜型IL-6レセプターに対してpH依存的な結合能を示した。さらに実施例9においてカニクイザルにおいてWTと比較して抗体が血漿中から消失するまでの時間、および、生体内の可溶型IL-6レセプターおよび膜型IL-6レセプターが抗体によって結合されている時間が大幅に延長することが見出されたH3pI/L73-IgG1と比較して、Fv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M71、Fv3-M73、Fv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73のいずれも膜型IL-6レセプターへのpH依存的結合が向上していることが見出された。 The obtained 10 types of pH-dependent binding clones showed pH-dependent binding ability to the membrane-type IL-6 receptor. Further, in Example 9, the time required for the antibody to disappear from plasma in the crab monkey as compared with WT, and the time during which the soluble IL-6 receptor and the membrane IL-6 receptor in vivo are bound by the antibody. Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M71, Fv3-M73, Fv4-IgG1, Fv4-IgG2, Fv4 compared to H3pI / L73-IgG1 for which was found to be significantly prolonged. Both -M58 and Fv4-M73 were found to have improved pH-dependent binding to the membrane-type IL-6 receptor.
〔実施例15〕可変領域と定常領域を最適化したpH依存的結合抗体のカニクイザルによるPK/PD試験
公知の高親和性抗IL-6レセプター抗体の作製
公知の高親和性抗IL-6レセプター抗体として、US 2007/0280945 A1に記載されている高親和性抗IL-6レセプター抗体であるVQ8F11-21 hIgG1(US 2007/0280945 A1, アミノ酸配列19および27)を発現させるため、動物細胞発現用ベクターを構築した。抗体可変領域については、合成オリゴDNAを組み合わせたPCR法(assembly PCR)により作製した。定常領域については、実施例1で使用した発現ベクターからPCR法により増幅した。Assembly PCR法により抗体可変領域と定常領域を結合させ、哺乳動物発現用ベクターへ挿入した。得られたH鎖およびL鎖DNA断片を哺乳動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。作製した発現ベクターを用い、発現・精製を行った。発現・精製は実施例1に記載した方法で行い、高親和性高IL-6レセプター抗体(high affinity Ab)を得た。
[Example 15] PK / PD test of pH-dependent binding antibody with optimized variable region and constant region using cynomolgus monkey
Preparation of Known High-Affinity Anti-IL-6 Receptor Antibody VQ8F11-21, which is a high-affinity anti-IL-6 receptor antibody described in US 2007/0280945 A1 as a known high-affinity anti-IL-6 receptor antibody. An animal cell expression vector was constructed to express hIgG1 (US 2007/0280945 A1, amino acid sequences 19 and 27). The antibody variable region was prepared by a PCR method (assembly PCR) combining synthetic oligo DNA. The constant region was amplified by the PCR method from the expression vector used in Example 1. The antibody variable region and the constant region were bound by the Assembly PCR method and inserted into a mammalian expression vector. The obtained H-chain and L-chain DNA fragments were inserted into a mammalian cell expression vector to prepare a target H-chain expression vector and L-chain expression vector. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art. Expression and purification were performed using the prepared expression vector. Expression and purification were carried out by the method described in Example 1 to obtain a high affinity high IL-6 receptor antibody (high affinity Ab).
カニクイザルによるPK/PD試験
pH依存的結合抗体であるH3pI/L73-IgG1およびFv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M73、Fv4-M73および公知の高親和性抗IL-6レセプター抗体(high affinity Ab)のカニクイザルにおける薬物動態および薬効を評価した。H3pI/L73-IgG1およびFv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M73、Fv4-M73をカニクイザルに0.5 mg/kgで静脈内に単回投与し、またhigh affinity Abは1.0 mg/kgで静脈内に単回投与し、投与前および経時的に採血した。実施例9と同様に各抗体の血漿中濃度の測定を行った。H3pI/L73-IgG1およびFv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M73、Fv4-M73、high affinity Abの血漿中濃度推移を図21に示した。カニクイザル膜型IL-6レセプターがどの程度中和されているかの薬効を評価するために、実施例9と同様に、抗体投与後3日目から10日目(high affinity Abに関しては6日目から10日目)までカニクイザルIL-6 5μg/kgを腰背部に連日皮下投与し、24時間後の各個体のCRP濃度を測定した。各抗体投与時のCRP濃度推移を図22に示した。カニクイザル可溶型IL-6レセプターがどの程度中和されているかの薬効を評価するために、実施例9と同様に、カニクイザル血漿中の非結合型のカニクイザル可溶型IL-6レセプター濃度を測定した。各抗体投与時の非結合型のカニクイザル可溶型IL-6レセプター濃度推移を図23に示した。
PK / PD test with cynomolgus monkey
Of the pH-dependent binding antibodies H3pI / L73-IgG1 and Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M73, Fv4-M73 and known high affinity anti-IL-6 receptor antibodies (high affinity Ab) The pharmacokinetics and efficacy in cynomolgus monkeys were evaluated. H3pI / L73-IgG1 and Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M73, Fv4-M73 were intravenously administered to cynomolgus monkeys at 0.5 mg / kg in a single dose, and high affinity Ab was 1.0 mg / kg. A single dose was administered intravenously, and blood was collected before and over time. The plasma concentration of each antibody was measured in the same manner as in Example 9. The changes in plasma concentrations of H3pI / L73-IgG1 and Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M73, Fv4-M73, and high affinity Ab are shown in FIG. In order to evaluate the efficacy of the cynomolgus monkey membrane-type IL-6 receptor, as in Example 9, 3 to 10 days after antibody administration (6 days for high affinity Ab). Until the 10th day), cynomolgus monkey IL-6 5 μg / kg was subcutaneously administered to the back of the lumbar region every day, and the CRP concentration of each individual was measured 24 hours later. The transition of CRP concentration at the time of administration of each antibody is shown in FIG. In order to evaluate the efficacy of the cynomolgus monkey soluble IL-6 receptor to what extent it is neutralized, the concentration of the unbound cynomolgus monkey soluble IL-6 receptor in the cynomolgus monkey plasma was measured as in Example 9. did. The transition of the concentration of the unbound cynomolgus monkey-soluble IL-6 receptor at the time of administration of each antibody is shown in FIG.
これより、H3pI/L73-IgG1と比較して、Fv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M73、Fv4-M73はいずれも抗体血漿中濃度が高く維持され、CRP濃度および非結合型のカニクイザル可溶型IL-6レセプター濃度が低く維持されていることが見出された。すなわち、これらはH3pI/L73-IgG1と比較して、膜型IL-6レセプターおよび可溶型IL-6レセプターが抗体によって結合されている時間(言い換えれば中和されている時間)が延長されていることが示された。 From this, compared with H3pI / L73-IgG1, Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M73, and Fv4-M73 all maintained high antibody plasma concentrations, and CRP concentration and unbound type. It was found that the concentration of cynomolgus monkey-soluble IL-6 receptor was kept low. That is, they have a longer time for the membrane IL-6 receptor and the soluble IL-6 receptor to be bound by the antibody (in other words, the time for neutralization) compared to H3pI / L73-IgG1. It was shown to be.
また、これらのpH依存的結合抗IL-6レセプター抗体は、1.0 mg/kgで投与した公知の高親和性抗IL-6レセプター抗体(high affinity Ab)と比較して、半分の投与量である0.5 mg/kgで同等以上の中和効果と持続性が確認されたことから、pH依存的結合抗体は公知の高親和性高IL-6レセプター抗体と比較して優れた中和効果と持続性を有することが明らかとなった。 In addition, these pH-dependent binding anti-IL-6 receptor antibodies are half the dose compared to the known high affinity anti-IL-6 receptor antibody (high affinity Ab) administered at 1.0 mg / kg. Since it was confirmed that the neutralizing effect and persistence were equal to or higher than those at 0.5 mg / kg, the pH-dependent binding antibody was superior in neutralizing effect and persistence as compared with the known high-affinity high-IL-6 receptor antibody. It became clear that it has.
表12に記した抗体のうち、本試験でカニクイザルによるPK/PD試験を実施しなかった抗体についても、H3pI/L73-IgG1と比較して、膜型IL-6レセプターへのpH依存的結合が向上していることが確認されていることから、これらについてもH3pI/L73-IgG1と比較して膜型IL-6レセプターおよび可溶型IL-6レセプターが抗体によって結合されている時間(言い換えれば中和されている時間、中和効果の持続性)が延長されていると考えられる。 Among the antibodies listed in Table 12, the antibodies that were not PK / PD tested by cynomolgus monkeys in this test also had pH-dependent binding to the membrane-type IL-6 receptor as compared with H3pI / L73-IgG1. Since it has been confirmed that these are also improved, the time during which the membrane-type IL-6 receptor and the soluble-type IL-6 receptor are bound by the antibody (in other words, in other words) compared with H3pI / L73-IgG1. It is considered that the duration of neutralization (duration of neutralization effect) is extended.
実施例9において、H3pI/L73-IgG1はWTと比較して、抗体が血漿中から消失するまでの時間、および、生体内の可溶型IL-6レセプターおよび膜型IL-6レセプターが抗体によって結合されている時間(中和効果の持続性)が大幅に延長することが見出されている。H3pI/L73-IgG1より中和効果の持続性に優れるFv1-M71、Fv1-M73、Fv2-IgG1、Fv3-M71、Fv3-M73、Fv4-IgG1、Fv4-IgG2、Fv4-M58、Fv4-M73はWTと比較した場合、著しく中和効果の持続性が改善されたと考えられる。 In Example 9, H3pI / L73-IgG1 was compared with WT for the time until the antibody disappeared from plasma, and the soluble IL-6 receptor and the membrane IL-6 receptor in vivo were affected by the antibody. It has been found that the time of binding (persistence of neutralizing effect) is significantly extended. Fv1-M71, Fv1-M73, Fv2-IgG1, Fv3-M71, Fv3-M73, Fv4-IgG1, Fv4-IgG2, Fv4-M58, Fv4-M73, which have a longer lasting neutralizing effect than H3pI / L73-IgG1 When compared with WT, it is considered that the persistence of the neutralizing effect was significantly improved.
これらのことから、抗IL-6レセプター抗体に対して、血漿中のpHであるpH7.4において強く抗原に結合し、エンドソーム内のpHであるpH5.8において抗原への結合を弱くしたpH依存的結合抗IL-6レセプター抗体は、抗IL-6レセプター抗体の患者への投与量や投与頻度を減らすことが可能であり、結果として総投与量を大幅に減らすことが可能となり、IL-6アンタゴニストとしての医薬品として極めて優れていると考えられる。 From these facts, it is pH-dependent that the anti-IL-6 receptor antibody strongly binds to the antigen at pH 7.4, which is the pH in plasma, and weakens the binding to the antigen at pH 5.8, which is the pH in endosomes. Anti-IL-6 receptor antibody can reduce the dose and frequency of administration of the anti-IL-6 receptor antibody to patients, and as a result, the total dose can be significantly reduced, and IL-6 can be significantly reduced. It is considered to be extremely excellent as a drug as an antagonist.
〔実施例16〕pH依存的に結合する抗IL-6抗体の作製
抗IL-6抗体の発現と精製
実施例1〜15におけるヒト化抗IL-6レセプター抗体において、ヒト化抗IL-6レセプター抗体の可変領域に対して、そのCDR配列を中心にヒスチジン等への置換を導入することによって、ヒト化抗IL-6レセプター抗体とIL-6レセプターとの結合にpH依存性を付与した抗体を複数創製することに成功し、それらは全てIL-6レセプターへ繰り返し結合し、PK/PDが大きく改善することが見出された。
[Example 16] Preparation of anti-IL-6 antibody that binds in a pH-dependent manner
Expression and purification of anti-IL-6 antibody In the humanized anti-IL-6 receptor antibody in Examples 1 to 15, the variable region of the humanized anti-IL-6 receptor antibody was subjected to histidine and the like centering on its CDR sequence. By introducing substitutions, we succeeded in creating multiple antibodies that impart pH dependence to the binding between humanized anti-IL-6 receptor antibody and IL-6 receptor, and all of them repeatedly bind to IL-6 receptor. However, it was found that PK / PD was greatly improved.
そこで、抗IL-6レセプター抗体とは異なる抗原に結合する抗体において同様の方法により、抗原と抗体との結合にpH依存性を付与できるかどうかを検討した。異なる抗原としてヒトIL-6を選択し、WO2004/039826に記載されたヒトIL-6に結合するH鎖(WT)(アミノ酸配列 配列番号:62)とL鎖(WT)(アミノ酸配列 配列番号:63)からなる抗IL-6抗体(anti-IL6 wild type)を作製した。当業者公知の方法で目的の抗体アミノ酸配列をコードする遺伝子断片を動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。Anti-IL6 wild typeの発現と精製は実施例1に記載した方法で行った。 Therefore, it was examined whether or not pH dependence can be imparted to the binding between the antigen and the antibody by the same method for an antibody that binds to an antigen different from the anti-IL-6 receptor antibody. Human IL-6 was selected as a different antigen and bound to human IL-6 described in WO2004 / 039826. H chain (WT) (amino acid sequence SEQ ID NO: 62) and L chain (WT) (amino acid sequence SEQ ID NO:: An anti-IL-6 antibody (anti-IL6 wild type) consisting of 63) was prepared. A gene fragment encoding the antibody amino acid sequence of interest was inserted into an animal cell expression vector by a method known to those skilled in the art to prepare an H chain expression vector and an L chain expression vector of interest. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art. Expression and purification of the Anti-IL6 wild type was carried out by the method described in Example 1.
pH依存的抗IL-6抗体の作製
H鎖(WT)(アミノ酸配列 配列番号:62)とL鎖(WT)(アミノ酸配列 配列番号:63)からなる抗IL-6抗体(anti-IL6 wild type)に対して、CDRのアミノ酸に対してヒスチジンへの置換を導入することで、抗体とIL-6の結合にpH依存性を付与する検討を行った。CDRのアミノ酸に対してヒスチジンへの置換を検討し、スクリーニングを行った結果、pH7.4における結合と比較して、pH5.5における結合が大幅に低下し、pH依存的な結合を示すクローンがいくつか得られた。pH依存的クローンにおけるヒスチジン置換箇所を表13に示した。そのうち、H鎖(c1)(アミノ酸配列 配列番号:64)とL鎖(c1)(アミノ酸配列 配列番号:65)からなるanti-IL6 clone1、および、H鎖(c1)(アミノ酸配列 配列番号:64)とL鎖(c2)(アミノ酸配列 配列番号:66)からなるanti-IL6 clone2、が挙げられた。Anti-IL6 clone1とanti-IL6 clone2の発現と精製は実施例1に記載した方法で行った。
Preparation of pH-dependent anti-IL-6 antibody
Against the anti-IL-6 wild type consisting of H chain (WT) (amino acid sequence SEQ ID NO: 62) and L chain (WT) (amino acid sequence SEQ ID NO: 63), against the amino acid of CDR It was investigated to impart pH dependence to the binding of the antibody and IL-6 by introducing a substitution with histidine. As a result of examining the substitution of the amino acid of CDR with histidine and screening, a clone showing a pH-dependent binding with a significantly reduced binding at pH 5.5 compared to the binding at pH 7.4 was found. I got some. The histidine substitution sites in pH-dependent clones are shown in Table 13. Among them, anti-IL6 clone1 consisting of H chain (c1) (amino acid sequence SEQ ID NO: 64) and L chain (c1) (amino acid sequence SEQ ID NO: 65), and H chain (c1) (amino acid sequence SEQ ID NO: 64). ) And the L chain (c2) (amino acid sequence SEQ ID NO: 66), anti-IL6 clone2. Expression and purification of Anti-IL6 clone1 and anti-IL6 clone2 were carried out by the method described in Example 1.
[表13] pH依存的クローンにおけるヒスチジン置換箇所
H32、H59、H61、H99
L53、L54、L90、L94
[Table 13] Histidine substitution sites in pH-dependent clones
H32, H59, H61, H99
L53, L54, L90, L94
pH依存的結合クローンのヒトIL-6への結合解析
上記で作製したanti-IL6 wild type、anti-IL6 clone1、および、anti-IL6 clone2の3種類について、Biacore T100 (GE Healthcare) を用いてpH5.5とpH7.4における抗原抗体反応の速度論的解析を実施した(バッファーはDPBS(-) pH7.4あるいはpH5.5, 150 mM NaCl)。アミンカップリング法によりrecomb-proteinA/G (Pierce) を固定化したセンサーチップ上に種々の抗体を結合させ、そこにアナライトとして適切な濃度に調製したヒトIL-6(TORAY)を注入した。測定は全て37℃で実施した。Biacore T100 Evaluation Software (GE Healthcare)を用い、結合速度定数 ka (1/Ms) 、および解離速度定数 kd (1/s) を算出し、その値をもとに解離定数 KD (M) を算出した(表14)。さらにそれぞれについてpH5.5とpH7.4のaffinity比を算出し、pH依存性結合を評価した。
Binding analysis of pH-dependent binding clones to human IL-6 pH5 of the three types prepared above, anti-IL6 wild type, anti-IL6 clone1, and anti-IL6 clone2, using Biacore T100 (GE Healthcare). Kinetic analysis of antigen-antibody reactions at .5 and pH 7.4 was performed (buffer DPBS (-) pH 7.4 or pH 5.5, 150 mM NaCl). Various antibodies were bound onto a sensor chip on which recomb-protein A / G (Pierce) was immobilized by the amine coupling method, and human IL-6 (TORAY) prepared at an appropriate concentration as an analyzer was injected therein. All measurements were performed at 37 ° C. Using Biacore T100 Evaluation Software (GE Healthcare), the binding rate constant ka (1 / Ms) and the dissociation rate constant kd (1 / s) were calculated, and the dissociation constant KD (M) was calculated based on the values. (Table 14). Furthermore, the affinity ratios of pH 5.5 and pH 7.4 were calculated for each, and the pH-dependent binding was evaluated.
[表14] IL-6に対するpH依存的結合クローンのIL-6への結合比較
[Table 14] Comparison of binding of pH-dependent binding clones to IL-6 to IL-6
それぞれについてpH5.5とpH7.4のaffinity比(KD(pH5.5)/KD(pH7.4))を算出した結果、ヒトIL-6に対するanti-IL6 wild type、anti-IL6 clone1、anti-IL6 clone2のpH依存性結合はそれぞれ0.8倍、10.3倍、13.5倍であり、いずれのクローンもWTと比較して10倍以上の高いpH依存的結合を示した。Anti-IL6 clone2のpH7.4とpH5.5でのセンサーグラムを図26に示した。 As a result of calculating the affinity ratio (KD (pH5.5) / KD (pH7.4)) of pH5.5 and pH7.4 for each, anti-IL6 wild type, anti-IL6 clone1, anti- The pH-dependent binding of IL6 clone2 was 0.8-fold, 10.3-fold, and 13.5-fold, respectively, and all clones showed 10-fold or higher pH-dependent binding compared to WT. The sensorgrams of Anti-IL6 clone2 at pH 7.4 and pH 5.5 are shown in FIG.
これより、抗IL-6レセプター抗体のみならず、抗IL-6抗体においても、CDR配列を中心にヒスチジン等のアミノ酸への置換を導入することによって、血漿中の中性条件下では抗原に強く結合し、エンドソーム中の酸性条件下では抗原との結合が低下するpH依存的な結合を有する抗体を作製することが可能であることが示された。実施例1〜15に示したとおり、pH依存的な結合を有する抗IL-6レセプター抗体がIL-6レセプターに繰り返し結合しPK/PDが大きく改善したことから、pH依存的な結合を有するanti-IL6 clone1、anti-IL6 clone2は、anti-IL6 wild typeと比較して、より多くの抗原に繰り返し結合しPK/PDが大きく改善すると考えられた。 From this, not only the anti-IL-6 receptor antibody but also the anti-IL-6 antibody is strongly resistant to the antigen under neutral conditions in plasma by introducing substitutions with amino acids such as histidine centering on the CDR sequence. It has been shown that it is possible to produce antibodies with pH-dependent binding that binds and reduces binding to the antigen under acidic conditions in the endosome. As shown in Examples 1 to 15, the anti-IL-6 receptor antibody having a pH-dependent binding repeatedly bound to the IL-6 receptor and the PK / PD was greatly improved. Therefore, the anti having a pH-dependent binding -IL6 clone1 and anti-IL6 clone2 were considered to repeatedly bind to more antigens and significantly improve PK / PD compared to anti-IL6 wild type.
〔実施例17〕pH依存的に結合する抗IL-31レセプター抗体の作製
抗IL-31レセプター抗体の発現と精製
実施例1〜15において、ヒト化抗IL-6レセプター抗体において、ヒト化抗IL-6レセプター抗体の可変領域に対して、そのCDR配列を中心にヒスチジン等への置換を導入することによって、ヒト化抗IL-6レセプター抗体とIL-6レセプターとの結合にpH依存性を付与した抗体を複数創製することに成功し、それらは全てIL-6レセプターへ繰り返し結合し、PK/PDが大きく改善することが見出された。
[Example 17] Preparation of anti-IL-31 receptor antibody that binds in a pH-dependent manner
Expression and purification of anti-IL-31 receptor antibody In Examples 1 to 15, in the humanized anti-IL-6 receptor antibody, histidine, etc., centered on the CDR sequence of the variable region of the humanized anti-IL-6 receptor antibody, etc. By introducing the substitution with, we succeeded in creating multiple antibodies that imparted pH dependence to the binding between the humanized anti-IL-6 receptor antibody and the IL-6 receptor, and all of them became IL-6 receptors. It was found that repeated binding resulted in a significant improvement in PK / PD.
そこで、抗IL-6レセプター抗体とは異なる抗原に結合する抗体において同様の方法により、抗原と抗体との結合にpH依存性を付与できるかどうかを検討した。異なる抗原としてマウスIL-31レセプターを選択し、WO2007/142325に記載されたマウスIL-31レセプターに結合するH鎖(WT)(アミノ酸配列 配列番号:67)とL鎖(WT)(アミノ酸配列 配列番号:68)からなる抗IL-31レセプター抗体(anti-IL31R wild type)を作製した。当業者公知の方法で目的の抗体アミノ酸配列をコードする遺伝子断片を動物細胞発現ベクターに挿入し、目的のH鎖発現ベクターおよびL鎖発現ベクターを作製した。得られた発現ベクターの塩基配列は当業者公知の方法で決定した。Anti-IL31R wild typeの発現と精製は実施例1に記載した方法で行った。 Therefore, it was examined whether or not pH dependence can be imparted to the binding between the antigen and the antibody by the same method for an antibody that binds to an antigen different from the anti-IL-6 receptor antibody. Mouse IL-31 receptor was selected as a different antigen, and H chain (WT) (amino acid sequence SEQ ID NO: 67) and L chain (WT) (amino acid sequence sequence) that bind to the mouse IL-31 receptor described in WO2007 / 142325. An anti-IL-31 receptor antibody (anti-IL31R wild type) consisting of No .: 68) was prepared. A gene fragment encoding the antibody amino acid sequence of interest was inserted into an animal cell expression vector by a method known to those skilled in the art to prepare an H chain expression vector and an L chain expression vector of interest. The base sequence of the obtained expression vector was determined by a method known to those skilled in the art. Expression and purification of Anti-IL31R wild type was performed by the method described in Example 1.
pH依存的抗IL-31レセプター抗体の作製
H鎖(WT)(アミノ酸配列 配列番号:67)とL鎖(WT)(アミノ酸配列 配列番号:68)からなる抗IL-31レセプター抗体(anti-IL31R wild type)に対して、CDRのアミノ酸に対してヒスチジンへの置換を導入することで、抗体とIL-31レセプターの結合にpH依存性を付与する検討を行った。CDRのアミノ酸に対してヒスチジンへの置換を検討し、スクリーニングを行った結果、pH7.4における結合と比較して、pH5.5における結合が大幅に低下し、pH依存的な結合を示すクローンがいくつか得られた。pH依存的クローンにおけるヒスチジン置換箇所を表15に示した。そのうちの一つとして、H鎖(c1)(アミノ酸配列 配列番号:69)とL鎖(WT)からなるanti-IL31R clone1が挙げられた。Anti-IL31R clone1の発現と精製は実施例1に記載した方法で行った。
Preparation of pH-dependent anti-IL-31 receptor antibody
Amino acid for CDR against anti-IL-31 receptor antibody (anti-IL31R wild type) consisting of H chain (WT) (amino acid sequence SEQ ID NO: 67) and L chain (WT) (amino acid sequence SEQ ID NO: 68). On the other hand, it was investigated to impart pH dependence to the binding between the antibody and the IL-31 receptor by introducing a substitution with histidine. As a result of examining the substitution of the amino acid of CDR with histidine and screening, a clone showing a pH-dependent binding with a significantly reduced binding at pH 5.5 compared to the binding at pH 7.4 was found. I got some. Table 15 shows the histidine substitution sites in the pH-dependent clones. As one of them, anti-IL31R clone1 consisting of H chain (c1) (amino acid sequence SEQ ID NO: 69) and L chain (WT) was mentioned. Expression and purification of Anti-IL31R clone1 was carried out by the method described in Example 1.
[表15] pH依存的クローンにおけるヒスチジン置換箇所
H33
[Table 15] Histidine substitution sites in pH-dependent clones
H33
pH依存的結合クローンの可溶型IL-31レセプターへの結合解析
上記で作製したanti-IL31R wild type、anti-IL31R clone1の2種類について、Biacore T100 (GE Healthcare) を用いてpH5.5とpH7.4における抗原抗体反応の速度論的解析を実施した(バッファーはDPBS(-) pH7.4あるいはpH5.5, 150 mM NaCl, 0.01% Tween20, 0.02% NaN3)。アミンカップリング法によりrecomb-proteinA/G (Pierce) を固定化したセンサーチップ上に種々の抗体を結合させ、そこにアナライトとして適切な濃度に調製した可溶型マウスIL-31レセプター(WO2007/142325に記載の方法で調製)を注入した。測定は全て25℃で実施した。Biacore T100 Evaluation Software (GE Healthcare)を用い、結合速度定数 ka (1/Ms) 、および解離速度定数 kd (1/s) を算出し、その値をもとに解離定数 KD (M) を算出した(表16)。さらにそれぞれについてpH5.5とpH7.4のaffinity比を算出し、pH依存性結合を評価した。
Binding analysis of pH-dependent binding clones to soluble IL-31 receptor For the two types of anti-IL31R wild type and anti-IL31R clone1 prepared above, pH 5.5 and
[表16] マウスIL-31レセプターに対するpH依存的結合クローンのマウスIL-31レセプターへの結合比較
[Table 16] Comparison of binding of pH-dependent binding clones to mouse IL-31 receptor to mouse IL-31 receptor
それぞれについてpH5.5とpH7.4のaffinity比(KD(pH5.5)/KD(pH7.4))を算出した結果、マウスIL-31レセプターに対するanti-IL31R wild type、anti-IL31R clone1のpH依存性結合はそれぞれ3.2倍、1000倍であり、clone1はWTと比較して300倍程度の高いpH依存的結合を示した。Anti-IL31R cloneのpH7.4とpH5.5でセンサーグラムを図27に示した。 As a result of calculating the affinity ratio (KD (pH5.5) / KD (pH7.4)) of pH5.5 and pH7.4 for each, the pH of anti-IL31R wild type and anti-IL31R clone1 with respect to the mouse IL-31 receptor Dependent binding was 3.2 times and 1000 times, respectively, and clone1 showed a pH-dependent binding that was about 300 times higher than that of WT. Sensorgrams of Anti-IL31R clone at pH 7.4 and pH 5.5 are shown in Figure 27.
これより、抗IL-6レセプター抗体と抗IL-6抗体のみならず、抗IL-31レセプター抗体においても、CDR配列を中心にヒスチジン等のアミノ酸への置換を導入することによって、血漿中の中性条件下では抗原に強く結合し、エンドソーム中の酸性条件下では抗原との結合が低下するpH依存的な結合を有する抗体を作製することが可能であることが示された。実施例1〜15に示したとおり、pH依存的な結合を有する抗IL-6レセプター抗体がIL-6レセプターに繰り返し結合しPK/PDが大きく改善したことから、pH依存的な結合を有するanti-IL31R clone1は、anti-IL31R wild typeと比較して、より多くの抗原に繰り返し結合しPK/PDが大きく改善すると考えられた。 From this, not only in anti-IL-6 receptor antibody and anti-IL-6 antibody, but also in anti-IL-31 receptor antibody, by introducing substitution with amino acids such as histidine centering on the CDR sequence, in the plasma. It has been shown that it is possible to produce antibodies with pH-dependent binding that binds strongly to the antigen under sexual conditions and reduces binding to the antigen under acidic conditions in the endosomes. As shown in Examples 1 to 15, the anti-IL-6 receptor antibody having a pH-dependent binding repeatedly bound to the IL-6 receptor and the PK / PD was greatly improved. Therefore, the anti having a pH-dependent binding -IL31R clone1 was considered to repeatedly bind to more antigens and significantly improve PK / PD compared to anti-IL31R wild type.
〔実施例18〕pH依存的結合抗体による抗原への繰り返し結合
マウス投与抗体の発現と精製
ヒト化IL-6レセプター抗体として、以下の4種類を作製した。IL-6レセプターに対してpH依存的な結合を示さない通常の抗体としてH(WT)(アミノ酸配列 配列番号:9)とL(WT)(アミノ酸配列 配列番号:10)からなるWT-IgG1、H54(アミノ酸配列 配列番号:70)とL28(アミノ酸配列 配列番号:12)からなるH54/L28-IgG1を、IL-6レセプターに対してpH依存的な結合を示す抗体として実施例3で作製したH170(アミノ酸配列 配列番号:4)とL82(アミノ酸配列 配列番号:7)からなるH170/L82-IgG1、および、実施例10で作製したVH3-IgG1(配列番号:23)とVL3-CK(配列番号:27)からなるFv4-IgG1を実施例1に示した方法で発現と精製を行った。
[Example 18] Repeated binding to an antigen by a pH-dependent binding antibody
Expression and purification of mouse-administered antibodies The following four types of humanized IL-6 receptor antibodies were prepared. WT-IgG1, consisting of H (WT) (amino acid sequence SEQ ID NO: 9) and L (WT) (amino acid sequence SEQ ID NO: 10), as a normal antibody that does not show pH-dependent binding to the IL-6 receptor, H54 / L28-IgG1 consisting of H54 (amino acid sequence SEQ ID NO: 70) and L28 (amino acid sequence SEQ ID NO: 12) was prepared in Example 3 as an antibody showing pH-dependent binding to the IL-6 receptor. H170 / L82-IgG1 consisting of H170 (amino acid sequence SEQ ID NO: 4) and L82 (amino acid sequence SEQ ID NO: 7), and VH3-IgG1 (SEQ ID NO: 23) and VL3-CK (sequence) prepared in Example 10. Fv4-IgG1 consisting of No .: 27) was expressed and purified by the method shown in Example 1.
各種抗体の可溶型IL-6レセプターへの結合解析
調製したWT-IgG1、H54/L28-IgG1、H170/L82-IgG1、および、Fv4-IgG1の4種類について、Biacore T100 (GE Healthcare) を用いてpH7.4およびpH5.8における抗原抗体反応の速度論的解析を実施した(バッファーは10 mM MES pH7.4、またはpH5.8, 150 mM NaCl, 0.05% Surfactant-P20)。アミンカップリング法によりrecomb-proteinA/G (Pierce) を固定化したセンサーチップ上に種々の抗体を結合させ、そこにアナライトとして適切な濃度に調製したSR344を注入した。各種抗体のSR344への結合および解離をリアルタイムに観測した。測定は全て37℃で実施した。Biacore T100 Evaluation Software (GE Healthcare)を用い、結合速度定数 ka (1/Ms) 、および解離速度定数 kd (1/s) を算出し、その値をもとに 解離定数 KD (M) を算出した(表17)。
Binding analysis of various antibodies to soluble IL-6 receptor Biacore T100 (GE Healthcare) was used for four types of prepared WT-IgG1, H54 / L28-IgG1, H170 / L82-IgG1, and Fv4-IgG1. A kinetic analysis of the antigen-antibody reaction at pH 7.4 and pH 5.8 was performed (buffer is 10 mM MES pH 7.4, or pH 5.8, 150 mM NaCl, 0.05% Surfactant-P20). Various antibodies were bound onto a sensor chip on which recomb-protein A / G (Pierce) was immobilized by the amine coupling method, and SR344 prepared at an appropriate concentration as an analyst was injected therein. The binding and dissociation of various antibodies to SR344 were observed in real time. All measurements were performed at 37 ° C. Using Biacore T100 Evaluation Software (GE Healthcare), the binding rate constant ka (1 / Ms) and the dissociation rate constant kd (1 / s) were calculated, and the dissociation constant KD (M) was calculated based on the values. (Table 17).
[表17] SR344に対する各種抗体の可溶型IL-6レセプターからの結合速度(ka)・解離速度(kd)、解離定数(KD)比較
[Table 17] Comparison of binding rate (ka), dissociation rate (kd), and dissociation constant (KD) of various antibodies against SR344 from soluble IL-6 receptor
それぞれについてpH5.8とpH7.4のアフィニティー(KD値)比を算出した結果、SR344に対するWT-IgG1、H54/L28-IgG1、H170/L82-IgG1、および、Fv4-IgG1のpH依存性結合(KD値の比)はそれぞれ1.6倍、0.7倍、61.9倍および27.3倍であった。また、それぞれについてpH5.8とpH7.4の解離速度(kd値)比を算出した結果、SR344に対するWT-IgG1、H54/L28-IgG1、H170/L82-IgG1、および、Fv4-IgG1のpH依存性解離速度(kd値の比)はそれぞれ2.9倍、2.0倍、11.4倍および38.8倍であった。これより、通常の抗体であるWT-IgG1とH54/L28-IgG1はpH依存的な結合をほとんど示さず、H170/L82-IgG1とFv4-IgG1はpH依存的な結合を示すことが確認された。また、これらの抗体のpH7.4におけるアフィニティー(KD値)はほぼ同等であったから、血漿中におけるSR344への結合は同程度であると考えられた。 As a result of calculating the affinity (KD value) ratio of pH 5.8 and pH 7.4 for each, pH-dependent binding of WT-IgG1, H54 / L28-IgG1, H170 / L82-IgG1 and Fv4-IgG1 to SR344 ( The ratio of KD values) was 1.6 times, 0.7 times, 61.9 times and 27.3 times, respectively. In addition, as a result of calculating the dissociation rate (kd value) ratio of pH 5.8 and pH 7.4 for each, the pH dependence of WT-IgG1, H54 / L28-IgG1, H170 / L82-IgG1 and Fv4-IgG1 with respect to SR344. The sexual dissociation rate (ratio of kd values) was 2.9 times, 2.0 times, 11.4 times and 38.8 times, respectively. From this, it was confirmed that the normal antibodies WT-IgG1 and H54 / L28-IgG1 showed almost no pH-dependent binding, and that H170 / L82-IgG1 and Fv4-IgG1 showed pH-dependent binding. .. Moreover, since the affinity (KD value) of these antibodies at pH 7.4 was almost the same, it was considered that the binding to SR344 in plasma was about the same.
マウスを用いた体内動態試験
ヒトIl-6レセプターを発現していないマウス(C57BL/6J;これらの抗ヒトIL-6レセプター抗体はマウスのIL-6レセプターに結合しない)にSR344(ヒトIL-6レセプター:実施例1で作製)を単独投与、もしくはSR344および抗ヒトIL-6レセプター抗体を同時投与した後のSR344および抗ヒトIL-6レセプター抗体の体内動態を評価した。SR344溶液(5μg/mL)もしくはSR344および抗ヒトIL-6レセプター抗体の混合溶液(それぞれ5μg/mL、0.1 mg/mL)を尾静脈に10 mL/kgで単回投与した。このとき、SR344に対して抗ヒトIL-6レセプター抗体は十分量過剰に存在することから、SR344はほぼ全て抗体に結合していると考えられる。投与後15分間、2時間、8時間、1日間、2日間、3日間、4日間、7日間、14日間、21日間、28日間で採血を行った。採取した血液は直ちに4℃、15,000 rpmで15分間遠心分離し、血漿を得た。分離した血漿は、測定を実施するまで-20℃以下に設定された冷凍庫に保存した。抗ヒトIL-6レセプター抗体としては、上述のWT-IgG1、H54/L28-IgG1、H170/L82-IgG1、および、Fv4-IgG1を使用した。
Immunodynamic test using mice SR344 (human IL-6) was applied to mice that did not express the human Il-6 receptor (C57BL / 6J; these anti-human IL-6 receptor antibodies do not bind to the mouse IL-6 receptor). Receptor: prepared in Example 1) was administered alone, or the pharmacokinetics of SR344 and anti-human IL-6 receptor antibody after simultaneous administration of SR344 and anti-human IL-6 receptor antibody were evaluated. A single dose of SR344 solution (5 μg / mL) or a mixed solution of SR344 and anti-human IL-6 receptor antibody (5 μg / mL and 0.1 mg / mL, respectively) was administered to the tail vein at 10 mL / kg. At this time, since the anti-human IL-6 receptor antibody is present in a sufficient amount in excess of SR344, it is considered that almost all SR344 is bound to the antibody. Blood was collected 15 minutes, 2 hours, 8 hours, 1 day, 2 days, 3 days, 4 days, 7 days, 14 days, 21 days, and 28 days after administration. The collected blood was immediately centrifuged at 4 ° C. and 15,000 rpm for 15 minutes to obtain plasma. The separated plasma was stored in a freezer set at -20 ° C or lower until the measurement was performed. As the anti-human IL-6 receptor antibody, the above-mentioned WT-IgG1, H54 / L28-IgG1, H170 / L82-IgG1, and Fv4-IgG1 were used.
ELISA法による血漿中抗ヒトIL-6レセプター抗体濃度測定
マウス血漿中の抗ヒトIL-6レセプター抗体濃度はELISA法にて測定した。まずAnti-Human IgG(γ-chain specific) F(ab')2 Fragment of Antibody (SIGMA) をNunc-Immuno Plate, MaxiSoup (Nalge nunc International)に分注し、4℃で1晩静置しAnti-Human IgG固相化プレートを作成した。血漿中濃度として0.8、0.4、0.2、0.1、0.05、0.025、0.0125μg/mLの検量線試料と100倍以上希釈したマウス血漿測定試料を調製し、これら検量線試料および血漿測定試料100μLに20 ng/mLのSR344を200μL加え、室温で1時間静置した。その後Anti-Human IgG固相化プレートに分注しさらに室温で1時間静置した。その後Biotinylated Anti-human IL-6 R Antibody(R&D)を室温で1時間反応させ、さらにStreptavidin-PolyHRP80 (Stereospecific Detection Technologies)を室温で1時間反応させ、TMB One Component HRP Microwell Substrate (BioFX Laboratories)を基質として用い発色反応を行い、1N-Sulfuric acid(Showa Chemical)で反応停止後、マイクロプレートリーダーにて450 nmの吸光度を測定した。マウス血漿中濃度は検量線の吸光度から解析ソフトウェアSOFTmax PRO(Molecular Devices)を用いて算出した。この方法で測定した静脈内投与後の血漿中抗体濃度推移を図28に示した。
Plasma anti-human IL-6 receptor antibody concentration measurement by ELISA method The anti-human IL-6 receptor antibody concentration in mouse plasma was measured by the ELISA method. First, Anti-Human IgG (γ-chain specific) F (ab') 2 Fragment of Antibody (SIGMA) was dispensed into Nunc-Immuno Plate, MaxiSoup (Nalge nunc International) and allowed to stand overnight at 4 ° C. Anti- A Human IgG-immobilized plate was prepared. Prepare a calibration curve sample having a plasma concentration of 0.8, 0.4, 0.2, 0.1, 0.05, 0.025, 0.0125 μg / mL and a mouse plasma measurement sample diluted 100-fold or more, and add 20 ng to 100 μL of these calibration curve sample and the plasma measurement sample. 200 μL of SR344 of / mL was added, and the mixture was allowed to stand at room temperature for 1 hour. Then, it was dispensed into an Anti-Human IgG-immobilized plate and allowed to stand at room temperature for 1 hour. After that, Biotinylated Anti-human IL-6 R Antibody (R & D) was reacted at room temperature for 1 hour, then Streptavidin-PolyHRP80 (Stereospecific Detection Technologies) was reacted at room temperature for 1 hour, and TMB One Component HRP Microwell Substrate (BioFX Laboratories) was used as a substrate. After the reaction was stopped with 1N-Sulfuric acid (Showa Chemical), the absorbance at 450 nm was measured with a microplate reader. The mouse plasma concentration was calculated from the absorbance of the calibration curve using the analysis software SOFTmax PRO (Molecular Devices). The transition of plasma antibody concentration after intravenous administration measured by this method is shown in FIG. 28.
電気化学発光法による血漿中SR344濃度測定
マウスの血漿中SR344濃度は電気化学発光法にて測定した。2000、1000、500、250、125、62.5、31.25 pg/mLに調整したSR344検量線試料および50倍以上希釈したマウス血漿測定試料を調製し、SULFO-TAG NHS Ester(Meso Scale Discovery)でルテニウム化したMonoclonal Anti-human IL-6R Antibody(R&D)およびBiotinylated Anti-human IL-6 R Antibody (R&D)およびWT-IgG1溶液を混合し37℃で1晩反応させた。その際のWT-IgG1の終濃度はサンプルに含まれる抗ヒトIL-6レセプター抗体濃度より過剰の333μg/mLであり、サンプル中のほぼ全てのSR344をWT-IgG1と結合した状態にすることを目的とした。その後、MA400 PR Streptavidin Plate(Meso Scale Discovery)に分注した。さらに室温で1時間反応させ洗浄後、Read Buffer T(×4)(Meso Scale Discovery)を分注し、ただちにSECTOR PR 400 reader(Meso Scale Discovery)で測定を行った。SR344濃度は検量線のレスポンスから解析ソフトウェアSOFTmax PRO(Molecular Devices)を用いて算出した。この方法で測定した静脈内投与後の血漿中SR344濃度推移を図29に示した。
Measurement of plasma SR344 concentration by electrochemiluminescence The plasma SR344 concentration of mice was measured by electrochemiluminescence. SR344 calibration curve samples adjusted to 2000, 1000, 500, 250, 125, 62.5, 31.25 pg / mL and mouse plasma measurement samples diluted 50-fold or more were prepared and converted to ruthenium by SULFO-TAG NHS Ester (Meso Scale Discovery). Monoclonal Anti-human IL-6R Antibody (R & D) and Biotinylated Anti-human IL-6 R Antibody (R & D) and WT-IgG1 solution were mixed and reacted at 37 ° C. overnight. At that time, the final concentration of WT-IgG1 was 333 μg / mL, which was more than the concentration of the anti-human IL-6 receptor antibody contained in the sample, and almost all SR344s in the sample should be bound to WT-IgG1. It was the purpose. After that, it was dispensed into MA400 PR Streptavidin Plate (Meso Scale Discovery). After further reacting at room temperature for 1 hour and washing, Read Buffer T (× 4) (Meso Scale Discovery) was dispensed and immediately measured with a
pH依存的結合による効果
pH依存的な結合を示さない抗体であるWT-IgG1とH54/L28-IgG1、および、pH依存的な結合を示す抗体であるH170/L82-IgG1とFv4-IgG1の抗体濃度推移に関しては、WT-IgG1、H54/L28-IgG1、および、Fv4-IgG1はほぼ同等であり、H170/L82-IgG1は若干早い消失を示した。血漿中濃度推移のデータを薬物動態解析ソフトWinNonlin(Pharsight)で解析した結果、WT-IgG1、H54/L28-IgG1、Fv4-IgG1、H170/L82-IgG1の血漿中半減期はそれぞれ21.0、28.8、26.2、7.5 dayであった。
Effect of pH-dependent binding
Regarding the changes in the antibody concentrations of WT-IgG1 and H54 / L28-IgG1 which are antibodies that do not show pH-dependent binding, and H170 / L82-IgG1 and Fv4-IgG1 which are antibodies that show pH-dependent binding, WT -IgG1, H54 / L28-IgG1 and Fv4-IgG1 were almost equivalent, and H170 / L82-IgG1 showed a slightly faster disappearance. As a result of analyzing the plasma concentration transition data with the pharmacokinetic analysis software WinNonlin (Pharsight), the plasma half-lives of WT-IgG1, H54 / L28-IgG1, Fv4-IgG1, and H170 / L82-IgG1 are 21.0 and 28.8, respectively. It was 26.2 and 7.5 days.
実施例2に記したとおり、抗原が可溶型抗原の場合、投与した抗体は血漿中で抗原に結合し、抗原と抗体の複合体の形で血漿中を滞留する。通常、抗体の血漿中滞留性はFcRnの機能により非常に長い(消失速度が非常に遅い)のに対して、抗原の血漿中滞留性は短い(消失速度が速い)ため、抗体に結合した抗原は抗体と同程度の長い血漿中滞留性を有する(消失が非常に遅い)ことになる。ヒト化IL-6レセプター抗体の抗原であるSR344(可溶型ヒトIL-6レセプター)を単独で投与した場合も同様にSR344は極めて早い消失を示した(血漿中半減期0.2 day)。SR344とpH依存的な結合を示さない通常の抗体であるWT-IgG1あるいはH54/L28-IgG1を同時に投与した場合、SR344の消失速度は著しく低下し、長い血漿中滞留性を示した(血漿中半減期:WT-IgG1 5.3 day、H54/L28-IgG1 6.3 day)。これはSR344が同時に投与した抗体にほぼ全て結合していため、上述のとおり抗体に結合したSR344はFcRnの機能により抗体と同程度の長い血漿中滞留性を有するためである。 As described in Example 2, when the antigen is a soluble antigen, the administered antibody binds to the antigen in plasma and stays in plasma in the form of an antigen-antibody complex. Normally, the plasma retention of an antibody is very long (the rate of elimination is very slow) due to the function of FcRn, whereas the retention of the antigen in plasma is short (the rate of elimination is fast), so that the antigen bound to the antibody Will have as long a plasma retention as the antibody (very slow to disappear). Similarly, when SR344 (soluble human IL-6 receptor), which is an antigen of humanized IL-6 receptor antibody, was administered alone, SR344 showed extremely rapid disappearance (plasma half-life 0.2 day). When SR344 and WT-IgG1 or H54 / L28-IgG1, which are normal antibodies showing no pH-dependent binding, were co-administered, the elimination rate of SR344 was significantly reduced, and long plasma retention was exhibited (in plasma). Half-life: WT-IgG1 5.3 day, H54 / L28-IgG1 6.3 day). This is because almost all of SR344 is bound to the antibody administered at the same time, and as described above, SR344 bound to the antibody has a long plasma retention similar to that of the antibody due to the function of FcRn.
SR344とpH依存的な結合を示す抗体であるH170/L82-IgG1あるいはFv4-IgG1を同時に投与した場合、SR344の消失はWT-IgG1あるいはH54/L28-IgG1を同時に投与した場合と比較して著しく速くなった(血漿中半減期:H170/L82-IgG1 1.3 day、Fv4-IgG1 0.6 day)。その傾向は特にFv4-IgG1で顕著であった。Fv4-IgG1のpH7.4におけるアフィニティーはWT-IgG1およびH54/L28-IgG1と同等以上であることから、SR344はほぼ全てFv4-IgG1に結合していると考えられる。Fv4-IgG1は、WT-IgG1とH54/L28-IgG1と比較して、同等あるいはやや長い血漿中滞留性を示し消失が遅いにもかかわらず、Fv4-IgG1に結合したSR344の消失は著しく速くなった。これは図4に示した本技術のコンセプトにより説明可能である。pH依存的な結合を示さない通常の抗体は、抗体−可溶型抗原複合体が血漿中においてピノサイトーシスによってエンドソームに取り込まれ、エンドソーム内の酸性条件下においてエンドソーム内に発現しているFcRnに結合し、FcRnへ結合した抗体−可溶型抗原複合体はそのまま細胞表面へ移行し再び血漿中に戻るため、抗体に結合した抗原は抗体と同程度の長い血漿中滞留性を有する(消失が非常に遅い)。一方、pH依存的な結合を示す抗体は、エンドソーム内の酸性条件下において抗原を解離するため、抗体のみFcRnに結合し再び血漿中に戻り、抗体から解離した抗原は血漿中に戻ることなくライソソームで分解されるため、抗原の消失は、pH依存的な結合を示さない抗体の場合と比較して消失が著しく速くなる。すなわち、SR344をpH依存的な結合を示さない抗体であるWT-IgG1あるいはH54/L28-IgG1と同時に投与した場合は、血漿中とエンドソーム内においてSR344はWT-IgG1あるいはH54/L28-IgG1と結合しているためSR344の消失は抗体と同程度に遅くなるが、SR344をpH依存的な結合を示す抗体であるH170/L82-IgG1あるいはFv4-IgG1と同時に投与した場合は、エンドソーム内の低pH環境下においてSR344が抗体から解離するためSR344の消失は極めて早くなる。すなわち、pH依存的な結合を示す抗体であるH170/L82-IgG1あるいはFv4-IgG1は、エンドソーム内の低pH環境下においてSR344が解離することから、FcRnによって再び血漿中に戻ったH170/L82-IgG1あるいはFv4-IgG1の多くはSR344が結合していないと考えられる。これよりpH依存的な結合を示す抗体は、図4に示すとおり、エンドソーム内の低pH環境下において抗原を解離し、抗原に結合していない状態でFcRnによって血漿中に戻ることで、血漿中で再度新しい抗原に結合することが可能となり、これを繰り返すことでpH依存的な結合を示す抗体は複数回抗原に繰り返し結合することが可能であることが示された。これは実施例7で示したようにBiacoreにおいて、pH依存的結合クローンが抗原へ繰り返し結合できることを反映しており、抗体の抗原へのpH依存的な結合を増強することで抗原へ繰り返し結合する回数を増大させることが可能である。 When SR344 and H170 / L82-IgG1 or Fv4-IgG1 which are antibodies showing pH-dependent binding are co-administered, the disappearance of SR344 is remarkable as compared with the co-administration of WT-IgG1 or H54 / L28-IgG1. It became faster (half-life in plasma: H170 / L82-IgG1 1.3 day, Fv4-IgG1 0.6 day). The tendency was particularly remarkable in Fv4-IgG1. Since the affinity of Fv4-IgG1 at pH 7.4 is equal to or higher than that of WT-IgG1 and H54 / L28-IgG1, it is considered that almost all SR344 is bound to Fv4-IgG1. Compared with WT-IgG1 and H54 / L28-IgG1, Fv4-IgG1 shows equivalent or slightly longer plasma retention and slower disappearance, but the disappearance of SR344 bound to Fv4-IgG1 is significantly faster. It was. This can be explained by the concept of the present technology shown in FIG. Normal antibodies that do not show pH-dependent binding are FcRn in which the antibody-soluble antigen complex is incorporated into endosomes by pinocytosis in plasma and expressed in endosomes under acidic conditions within endosomes. Since the antibody-soluble antigen complex that binds and binds to FcRn migrates to the cell surface as it is and returns to the plasma again, the antigen bound to the antibody has a long retention in plasma similar to that of the antibody (disappearance). Very slow). On the other hand, an antibody showing pH-dependent binding dissociates the antigen under acidic conditions in the endosome, so only the antibody binds to FcRn and returns to plasma again, and the antigen dissociated from the antibody does not return to plasma but lysosome. The disappearance of the antigen is significantly faster than that of an antibody that does not show pH-dependent binding. That is, when SR344 is co-administered with WT-IgG1 or H54 / L28-IgG1, which is an antibody that does not show pH-dependent binding, SR344 binds to WT-IgG1 or H54 / L28-IgG1 in plasma and endosomes. Therefore, the disappearance of SR344 is as slow as that of the antibody, but when SR344 is administered at the same time as H170 / L82-IgG1 or Fv4-IgG1 which is an antibody showing pH-dependent binding, the pH in the endosome is low. Since SR344 dissociates from the antibody in the environment, SR344 disappears extremely quickly. That is, H170 / L82-IgG1 or Fv4-IgG1, which is an antibody showing pH-dependent binding, dissociates SR344 in a low pH environment in endosomes, so that H170 / L82-re returned to plasma by FcRn. Most of IgG1 or Fv4-IgG1 is considered not to be bound by SR344. As shown in FIG. 4, the antibody showing pH-dependent binding dissociates the antigen in a low pH environment in the endosome and returns to plasma by FcRn in a state where it is not bound to the antigen. It became possible to bind to a new antigen again, and by repeating this, it was shown that an antibody showing pH-dependent binding can repeatedly bind to the antigen multiple times. This reflects that the pH-dependent binding clone can repeatedly bind to the antigen in Biacore as shown in Example 7, and repeatedly binds to the antigen by enhancing the pH-dependent binding of the antibody to the antigen. It is possible to increase the number of times.
抗原が可溶型抗原の場合、血漿中の中性条件下で抗体に結合した抗原がエンドソーム内で解離し抗体がFcRnにより血漿中に戻れば、抗体は再び血漿中の中性条件下で抗原に結合できるため、エンドソーム内の酸性条件下で抗原を解離する性質を有する抗体は抗原に複数回結合可能である。抗体に結合した抗原がエンドソーム内で解離しない場合(抗原は抗体に結合したまま血漿中に戻る)と比較して、抗体に結合した抗原がエンドソーム内で解離する場合は、抗原はライソソームに運ばれ分解されるため抗原の血漿中からの消失速度は増加する。すなわち、血漿中から抗原が消失する速度を指標として抗体が抗原に複数回結合可能であるか否かを判断することも可能である。抗原の血漿中からの消失速度の測定は、例えば、本実施例に示したように抗原と抗体を生体内に投与し、投与後の血漿中の抗原濃度を測定することにより行うことも可能である。 When the antigen is a soluble antigen, if the antigen bound to the antibody under neutral conditions in plasma dissociates in the endosome and the antibody returns to plasma by FcRn, the antibody is again antigen under neutral conditions in plasma. An antibody having the property of dissociating an antigen under acidic conditions in the endosome can bind to the antigen multiple times. When the antigen bound to the antibody dissociates in the endosome, the antigen is carried to the lysosome, as compared to the case where the antigen bound to the antibody does not dissociate in the endosome (the antigen remains bound to the antibody and returns to plasma). Since it is degraded, the rate of elimination of the antigen from plasma increases. That is, it is also possible to determine whether or not the antibody can bind to the antigen a plurality of times by using the rate at which the antigen disappears from plasma as an index. The rate of elimination of the antigen from plasma can be measured, for example, by administering the antigen and antibody in vivo as shown in this example and measuring the antigen concentration in plasma after administration. is there.
pH依存的な結合を示さない通常の抗体と比較して、pH依存的な結合を示す抗体は、一つの抗体が複数回抗原に繰り返し結合することが可能であるため、抗体の投与量の大幅な低減と投与間隔の大幅な延長が可能になると考えられる。 Compared to normal antibodies that do not show pH-dependent binding, antibodies that show pH-dependent binding have a large dose of antibody because one antibody can repeatedly bind to the antigen multiple times. It is thought that this can be reduced and the dosing interval can be significantly extended.
本メカニズムによる複数回の抗原への繰り返し結合は、pH依存的な抗原抗体反応に立脚していることから、如何なる抗原であっても血漿中のpH7.4で結合し、エンドソーム内の酸性pHで抗原から解離するpH依存的な結合を示す抗体を作製することができれば、一つの抗体が複数回抗原に繰り返し結合することが可能である。すなわち、本技術はIL-6レセプター、IL-6、IL-31レセプターのみならず、抗原の種類に依らず、如何なる抗原に対する抗体に対しても一般に適応可能な技術として有用である。 Since the repeated binding to multiple antigens by this mechanism is based on a pH-dependent antigen-antibody reaction, any antigen binds at pH 7.4 in plasma and at acidic pH in endosomes. If an antibody showing pH-dependent binding that dissociates from an antigen can be produced, one antibody can repeatedly bind to the antigen multiple times. That is, this technique is useful as a technique that can be generally applied not only to IL-6 receptor, IL-6, and IL-31 receptors but also to antibodies against any antigen regardless of the type of antigen.
Claims (50)
(a)pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b)pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c)pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程。 A method for screening antigen-binding molecules, which comprises the following steps,
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5.
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程。 A method for screening antigen-binding molecules, which comprises the following steps,
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) A step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5.
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程。 A method for screening an antigen-binding molecule whose binding activity at the first pH is higher than that at the second pH, which comprises the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) A step of obtaining an eluted antigen-binding molecule.
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程。 A method for screening an antigen-binding molecule whose binding activity at the first pH is higher than that at the second pH, which comprises the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) A step of obtaining an eluted antigen-binding molecule.
(a) pH6.7〜pH10.0における抗原結合分子の抗原結合活性を得る工程、
(b) pH4.0〜pH6.5における抗原結合分子の抗原結合活性を得る工程、
(c) pH6.7〜pH10.0での抗原結合活性がpH4.0〜pH6.5での抗原結合活性より高い抗原結合分子を選択する工程、
(d) (c)で選択された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。 Method for producing antigen-binding molecule, which comprises the following steps,
(a) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 6.7 to pH 10.0,
(b) Step of obtaining the antigen-binding activity of the antigen-binding molecule at pH 4.0 to pH 6.5,
(c) A step of selecting an antigen-binding molecule whose antigen-binding activity at pH 6.7 to pH 10.0 is higher than that at pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule selected in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
(a) pH6.7〜pH10.0の条件下で抗原結合分子を抗原に結合させる工程、
(b) (a)の抗原に結合した抗原結合分子をpH4.0〜pH6.5の条件下に置く工程、
(c) pH4.0〜pH6.5の条件下で解離した抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。 Method for producing antigen-binding molecule, which comprises the following steps,
(a) Step of binding an antigen-binding molecule to an antigen under the conditions of pH 6.7 to pH 10.0,
(b) The step of placing the antigen-binding molecule bound to the antigen of (a) under the conditions of pH 4.0 to pH 6.5,
(c) Step of obtaining an antigen-binding molecule dissociated under the conditions of pH 4.0 to pH 6.5,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
(a) 抗原を固定したカラムに第一のpH条件下で抗原結合分子を結合させる工程、
(b) 第一のpH条件下でカラムに結合した抗原結合分子を、第二のpH条件下でカラムから溶出する工程、
(c) 溶出された抗原結合分子を取得する工程、
(d) (c)で取得された抗原結合分子をコードする遺伝子を得る工程、
(e) (d)で得られた遺伝子を用いて抗原結合分子を製造する工程。 A method for producing an antigen-binding molecule whose binding activity at the first pH is higher than that at the second pH, which comprises the following steps.
(a) A step of binding an antigen-binding molecule to an antigen-immobilized column under the first pH condition,
(b) A step of eluting the antigen-binding molecule bound to the column under the first pH condition from the column under the second pH condition.
(c) Step of obtaining the eluted antigen-binding molecule,
(d) The step of obtaining the gene encoding the antigen-binding molecule obtained in (c),
(e) A step of producing an antigen-binding molecule using the gene obtained in (d).
(a) 抗原結合分子ライブラリーを、抗原を固定したカラムに第一のpH条件下で結合させる工程、
(b) カラムから第二のpH条件下で抗原結合分子を溶出する工程、
(c) 溶出された抗原結合分子をコードする遺伝子を増幅する工程、
(d) 溶出された抗原結合分子を取得する工程、
(e) (d)で取得された抗原結合分子をコードする遺伝子を得る工程、
(f) (e)で得られた遺伝子を用いて抗原結合分子を製造する工程。 A method for producing an antigen-binding molecule whose binding activity at the first pH is higher than that at the second pH, which comprises the following steps.
(a) The step of binding the antigen-binding molecule library to a column on which the antigen is immobilized under the first pH condition.
(b) The step of eluting the antigen-binding molecule from the column under the second pH condition,
(c) A step of amplifying a gene encoding an eluted antigen-binding molecule,
(d) Step of obtaining the eluted antigen-binding molecule,
(e) The step of obtaining the gene encoding the antigen-binding molecule obtained in (d),
(f) A step of producing an antigen-binding molecule using the gene obtained in (e).
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